Method for automatically configuring devices including a network adapter without manual intervention and without prior configuration information

ABSTRACT

A system for configuring a network adapter of a computer without user intervention. Device information for the devices of the computer, including each network adapter, is collected to uniquely identify the devices and to describe the device characteristics associated with the operation of those devices with the computer. Computer resources, which support the functions of the devices within the computer, are allocated based upon this device information. This allocation process prevents a potential conflicting use of computer resources by the installed devices. A device driver, which enables communications between a corresponding device and the computer, is also identified and loaded for each of the devices in response to the allocation of computer resources. In response to loading the driver for each network adapter, each network configuration routine or layer for a particular interface of the corresponding network adapter is identified. In response to the identification of these layers, each identified layer for the particular interface is loaded. In turn, layers are identified and loaded for each of the remaining interfaces of the corresponding network adapter.

CROSS REFERENCE TO RELATED APPLICATION

This application is a division of U.S. patent application Ser. No. 08/838,875, filed Apr. 9, 1997, now U.S. Pat. No. 6,003,097, which is a continuation of U.S. patent application Ser. No. 08/355,403, filed Dec. 13, 1994, now U.S. Pat. No. 5,655,148 now Pat. No. 5,787,246.

RELATED APPLICATION

This application is a continuation-in-part of U.S. patent application Ser. No. 08/250,698, entitled “System for Configuring Devices for a Computer System,” filed on May 27, 1994.

TECHNICAL FIELD

The present invention relates to data processing systems and, more particularly described, relates to configuring devices for operation with a computer without user intervention.

BACKGROUND OF THE INVENTION

The process of installing a peripheral device or an add-on type adapter board for use with a personal computer can be a relatively frustrating experience for the typical computer user. Nevertheless, a computer typically will not operate with a newly installed component until the user has completed a proper allocation of resources. Computer resources are allocated during a configuration process to permit the conflict-free use of the limited resources. To configure the computer, the user often must complete a relatively complex series of technical tasks. Thus, the difficulties faced by many users during the configuration process are emphasized by the absence of an automated process for resolving resource conflicts.

For many personal computers, neither the operating system nor the application programs running on the computer can determine which hardware components are connected to the computer. Likewise, the various hardware components connected to the computer often fail to detect the occurrence of a conflict between different hardware devices that attempt to share the same resource. Accordingly, a user typically must resolve a resource conflict by first identifying the problem and thereafter experimenting with hardware and software configurations in an attempt to correct the resource conflict.

When attempting to tackle hardware and software integration issues, the user is exposed to technical concepts that can be somewhat confusing for those without technical training, such as computer architecture issues, including hardware interrupts, direct memory access (DMA) channels, memory addresses, and input/output (I/O) ports. Likewise, many common configuration tasks require the user to be familiar with the finer details of the computer's operating system, including system configuration files, such as Autoexec.Bat, Config.Sys, and *.Ini files. In view of these technical concepts, some users find the configuration process so intimidating that they refuse to consider upgrading a component of their personal computer or connecting a new peripheral device to add a new capability to their computer.

Unlike today, early personal computers required minimum coordination between the computer hardware and software components. Users were presented with few difficult configuration issues after the initial installation of the computer. A limited number of peripheral devices were commercially available for supplementing the processing functions of the personal computer. In addition, early personal computers were primarily used for dedicated tasks, such as word processing or calculating financial information with a spreadsheet program, at a fixed desktop location.

In contrast, present computers are often portable systems that can be regularly connected to different peripheral devices and external systems. There exists many more computer peripheral devices that require the use of resources during computer operation than the limited quantity of available resources. Furthermore, a user can harness the powerful computing operations of a present personal computer to complete numerous tasks outside the traditional realm of word processing and financial calculations, such as graphics, audio, and video. For example, numerous peripheral devices and add-on systems are now commercially available to enable the user to customize the functions and operating characteristics of a personal computer. Docking-type computers enable a user to operate a mobile computer at either a base station or in remote locations. Thus, the rapid acceptance of portable computing and the multi-faceted uses of the personal computer emphasize the need for supplying a “user friendly” system that configures new hardware or software devices for use with the computer.

The Industry Standard Architecture (ISA) standard is a widely used bus architecture for personal computers. The ISA expansion bus, which is commonly associated with the IBM Personal Computer AT and other compatible computers, provides a 16-bit bus that supports the connection of adapter boards within the computer. The ISA bus structure requires allocation of resources, such as hardware interrupts, DMA channels, memory addresses, and I/O ports, among multiple ISA-compatible adapter boards connected to the ISA expansion bus. However, the ISA standard does not define a hardware or software mechanism for allocating those resources for use by the installed adapter boards. Consequently, configuration of the ISA adapter boards is typically completed by connecting jumper blocks or changing switch settings on the boards to change the decode maps for memory and I/O ports and to direct the DMA channels and interrupt signals to various pins along the expansion bus. Furthermore, system configuration program files of the operating system may need to be updated to reflect any modifications to the resource allocation.

Alternative expansion bus standards, such as the Micro Channel Architecture (MCA) and the Extended Indust Standard Architecture (EISA) standards, have limited hardware and software mechanisms to identify resources requested by a peripheral device and to resolve resource conflicts. However, these mechanisms are not implemented by the computer's operating system and are not compatible with the large installed base of personal computers based on the ISA standard. Furthermore, computers implementing the MCA and EISA standards are generally more expensive than ISA-compatible computers and lack the variety of add-on adapter boards and peripheral devices available for use with ISA-compatible computers.

To address the issue of configuration management, the computer industry is at present offering full-featured computers having preconfigured hardware and preinstalled software, thereby eliminating the need for a user to conduct the installation and configuration tasks for the purchased computer. However, this is a somewhat limited solution because vendors typically market a computer having a standard configuration of hardware and software components. Thus, this approach defeats the flexibility offered by the ISA bus expansion structure because users cannot obtain a computer capable of performing a customized function through this standardized configuration approach.

To overcome the frustration of users with present complicated configuration processes, it would be desirable to provide a system for automatically configuring a peripheral device or adapter board for a computer. A system is needed to enable a user to simply connect a device to the computer, turn on the computer, and have the device properly work with the computer. There is a further need for a system that determines the optimal configuration for its resources and enables application programs to fully utilize the available resources.

In recognition of the problems of prior configuration processes, the present invention provides a system that permits easy installation and configuration of devices which are capable of identifying themselves and declaring their services and resource requirements to the computer. The device identification and resource requirement information enable the system to determine and establish a working configuration for all devices connected to the computer, and to load the appropriate device drivers. In this manner, the present invention supports a variety of computer bus architectures and device classes. Accordingly, the present invention efficiently allocates system resources between the devices of the computer without substantial user intervention.

SUMMARY OF THE INVENTION

The problems associated with the manual installation and configuration of adapter boards and peripheral devices for computers are solved by the principles of the present invention. The present invention provides a system for configuring the hardware and software components of a computer by optimally allocating system resources for use by computer devices.

The present invention enables a user of a computer to install a new device by connecting the device to the computer, powering the computer, and using the computer to take advantage of the function supplied by the new device. Likewise, the present invention permits a user to insert a mobile computer into a base station while both the mobile computer and the base station are powered and to reconfigure the mobile computer for operation with the devices connected to the base station. Thus, the present invention addresses the needs of computer users by supplying a computer-implemented process for configuring devices for a computer and for accommodating seamless dynamic configuration changes of the computer.

A system constructed in accordance with the present invention configures devices of a computer by identifying the devices, determining the desired usage of the resources of the computer, detecting and resolving potential conflicting uses of the resources, and allocating resources for use by the devices. An operating system runs on the computer and supports these configuration tasks.

The computer includes various resources, including interrupts, direct memory access (DMA) channels, memory addresses, and input/output (I/O) ports, at least one system bus, and devices. System busses are components that supply physical connections to devices. Each of the devices is connected to one of the system busses of the computer.

The system busses can be compatible with a variety of bus architectures, including the Industry Standard Architecture (ISA), Micro Channel Architecture (MCA) and Extended Industry Standard Architecture (EISA) bus standards, as well as Personal Computer Memory Card International Association (PCMCIA), Small Computer Systems Interface (SCSI), Personal Computer Interface (PCI), Enhanced Capabilities Parallel (ECP), Vesa Local Bus (VL), Integrated Drive Electronics (IDE), and other bus standards. Typical devices supply the functions of system-level components, such as fixed and floppy disk controllers, display, keyboard, and mouse controllers, and serial and parallel controllers, and implement the functions offered by numerous add-on type adapter boards and peripheral devices.

Briefly described, the method for configuring the devices of the computer is started by collecting device information for each of the devices of the computer. This device information acquisition process permits the unique identification of the devices and the description of device characteristics associated with the operation of devices with the computer. A device driver, which enables communications between a corresponding device and the computer, is thereafter identified for each of the devices in response to the device information. The resources, which support the functions of the devices within the computer, are allocated based upon the device information. This allocation process prevents any potential conflicting use of the resources by the devices. In response to resource allocation, the devices are configured and device drivers for the devices are loaded. The devices are thereafter activated for operation with the computer.

More particularly described, the present invention configures devices of a computer based upon the collection of information about the devices and their connections to the system busses of the computer. To collect the device information, a particular device is detected on the system bus of interest and thereafter assigned a device identification code that identifies the particular device as being connected to the selected system bus. At least a portion of the device identification code, specifically an identification code, uniquely identifies the detected device. Logical configuration data, which supplies configuration requirements for operating the particular device with the computer, is also obtained for the detected device. This collection process is repeated until device information is eventually collected for each of the devices for all system busses of the computer.

The device information is stored within computer memory, such as volatile memory, to support the present configuration operation. At least a portion of the system memory is allocated for the storage of device information within a tree-like structure of device nodes. Each device connected to the computer is represented by a device node that stores associated device information. Furthermore, if an identified device represents a newly installed device for the computer, then this device information also can be stored in nonvolatile computer memory, such as a fixed disk, to supply an archival source of such information for future configuration tasks. A computer database having a hierarchical data arrangement is typically used to store this archival device information.

The collection of device information, which is also described as enumeration, is initiated in response to dynamic events that cause an asynchronous change in the operating state of the computer. These events typically affect the use of the resources by the devices of the computer and include: powering the computer; connecting another device to a system bus; removing a device from a system bus; and inserting the computer into or removing the computer from an expansion unit or a docking station.

The collection of device information supplies data that supports the identification of device drivers for the identified devices. A device driver can be obtained from one of several alternative sources of the computer, including selected files of the operating system installed on the computer, the device itself, a computer database maintained by the computer, or from the user via a disk containing the device driver. In general, the device driver for a device is often obtained by accessing a selected program file stored on either a flexed disk or another type of mass memory storage device of the computer.

If the devices of the computer include at least one network adapter, then the system for configuring devices of the computer further includes (1) the identification of “virtual devices” or layers connected to “virtual busses” or interfaces and (2) the loading of the identified layers for each of the interfaces. The layers of a network system typically include protocols, rredirectors, and servers, and the interfaces include an interface between the network adapter and the protocols and multiple interfaces between the protocols and associated redirectors and/or servers.

In response to loading the driver for the network adapter, each layer for a particular interface is identified and the layers are subsequently loaded. The layer identification and loading steps are repeated for each layer associated with the remaining interfaces for the network adapter.

To identify the layers for a particular interface, a database of the computer is searched to locate a first entry having an interface identification code that is associated with the particular interface. The first entry also can include one or more layer identification codes that uniquely define the identity of the layers for this interface.

To load an identified layer, a second entry having the layer identification code for this layer is located within the computer database. The second entry also can include a driver identification code that uniquely defines a driver for this layer. By using the driver identification code as a key to search the database, a third entry is then located within the database. The third entry can contain configuration parameters for the driver for the identified layer. In response to this driver-related information, the driver is loaded within system memory of the computer. The configuration parameters are supplied to the driver to complete the loading operation.

The computer database can contain device information associated with a particular device, including information for that particular device, which is also described as a primary device, and information for devices that are “compatible” with the primary device. For example. a first manufacturer's device may be compatible with a second manufacturer's device because both devices perform the same function and conform to an industry standard for operations. If the devices are compatible, a device driver for the first device often can be used to enable the operations of the second device and, likewise, a device driver for the second device can be used with the first device. Thus, a compatible device driver, if available, may be used to enable communications of the particular device with the computer.

The stored device information for a particular device typically can be accessed by searching in the computer database for a location or a record that contains the identification code for the desired device. Thus, the identification code can be used as an entry key to search the records of the computer database. If the device information in a selected record describes the primary device, then the device driver intended for primary use with that device is maintained by the computer and is available to support the device operations. Likewise, a compatible device driver is maintained by the computer if compatible device information is stored within the selected record and associated with the particular device.

By convention, the primary device driver is typically selected to support the computer operations of the primary device over any of the device drivers for compatible devices. However, if the device driver for the primary device is not available, then a device driver for a compatible device is selected. In this event, if the compatible device information lists more than one device that is compatible with the particular device, then the compatible device having the highest priority or ranking is selected and used to support the operations of the particular device.

If neither the primary device driver nor a compatible device driver is available on the computer, then the user can be requested to supply a substitute device driver that supports the operation of the device with the computer. This request is typically supplied as a textual statement displayed on a display or monitor for the computer or as an audio prompt generated by the computer. In response to the request, the user can insert within the proper computer drive a flexible disk or other appropriate electronic media containing the device driver, thereby permitting the computer to access the device driver. The device driver then can be stored within an appropriate mass memory storage device and used to enable the communications between the particular device and the computer.

Resources, which typically include a finite set of resource elements, are allocated by first analyzing the device information to detect whether the devices require a potential conflicting use of resource elements for operation of the devices with the computer. The desired resource element is assigned for use by a device if this resource assignment does not conflict with the use of that particular resource by another device. A resource element is available for use by a device if this element is neither reserved nor assigned for use by another device. Some resource elements are typically reserved for use by selected devices to insure the compatibility of the present invention with existing devices. Thus, if at least two of the devices require use of an identical resource element, then this potential resource conflict is arbitrated and resolved in an iterative manner based upon the device information and the finite resources of the computer. The resources are then assigned for use by the devices based upon this conflict-free solution.

In response to allocating the assigned resources to the devices, the devices are configured for operation with the computer. Each device driver is loaded for use by the corresponding devices and the devices are activated for operation with the computer.

Focusing upon another aspect of the present invention, a system is provided for supporting the bus-specific operations of devices connected to a system bus of a computer. This system, which is alternatively referred to as an enumerator or a bus driver, is assigned to operate with a specific system bus and is programmed to recognize the operating parameters of the assigned bus. Each system bus typically requires a unique configuration process that is based upon the architecture of the bus. The enumerator, which can be part of an operating system, directly supports the configuration of devices on its assigned bus by accessing device information for those devices and storing this data with a central memory. This enables an operating system for the computer to be independent of the characteristics of a computer bus architecture because bus-specific information is handled by an abstraction layer, in this case, the enumerator.

The enumerator can perform three primary operations, specifically (1) detecting dynamic events causing an asynchronous change in the operating state of the computer; (2) enumerating each of the devices connected to the assigned system bus in response to the detection of a dynamic event; and (3) supplying assigned resources to each of the devices in response to an allocation of resources. To implement these operations, the enumerator can include one or more elements that are responsible for those functions, namely an enumerate element, a configure element, and an event detect element. These functions are typically defined by the characteristics of its assigned system bus.

The enumerate element includes a detection module for detecting a particular device on the system bus and a collection module for retrieving device information from the particular device. The collection module obtains device information from the detected device and stores this data within device nodes of the computer memory to maintain an up-to-date inventory of the devices on the assigned system bus. Thus, the detection and collection modules operate in tandem to enumerate these devices. The computer memory can be a hierarchical database structure formed by a tree-like structure containing the device nodes, which represent each of the detected devices.

The configure element can include a receive module for receiving the allocation of assigned resource elements, an assigned resource storage module for storing the assigned resources within the device nodes of the computer memory, and a transmit module for supplying instructions about the assigned resources to the appropriate devices. In response to the assigned resources, the configure element accesses the device nodes in the computer memory and stores the appropriate resource element assignments.

The event detect element typically can detect the installation of a new device on the assigned system bus or the removal of an existing device. For example, device installation or removal can be detected by intercepting a particular interrupt signal or by periodically polling all of the available sockets of the bus to determine the installed devices. Likewise, the event detect element can detect the insertion of a computer into or the removal of a computer from a docking station. The event detect element is further responsive to booting the computer or the power state for the computer. In response to one of these events, the event detect element can supply the event detection information to the enumerate element, thereby initiating the enumeration process. The event detect element also can be responsive to certain query-type instruction signals containing commands for actions by the enumerator. These commands typically include: delete device information in a designated device node because the associated device has been removed from the computer, stop a present operation, and start a new operation.

Turning now to the enumeration process, a method is provided for identifying devices connected to a system bus of a computer having resources. First, a particular device is detected on the system bus. For example, for the widely used ISA bus, devices are detected by instructing each of the devices to enter an inactive state, thereby disabling the function of the device. The detected device on the ISA bus is then isolated from the remaining devices to enable interference-free communication with the detected device. In contrast, for the PCMCIA bus, a particular device is detected by selecting the socket supplying the connection for that device. Thus, it can be seen that device detection is a bus-dependent operation and may vary among different bus architectures.

A device identification code is thereafter assigned to the detected device. The device identification code, which includes an identification code and a system bus code appended to the identification code, typically identifies this device as a certain device type that is connected to the system bus. The identification code typically contains a string of characters, such as American Standard Code for Information Interchange (ASCII) characters, which uniquely define the particular device. The identification code is useful for defining both the manufacturer of the associated component and the type of device, and for distinguishing between identical types of devices connected to the same system bus. The system bus code uniquely identifies the system bus associated with the connected device.

Logical configuration data is also obtained for the particular device to acquire the configuration requirements for operating the particular device with the computer. The resources of a computer generally offer a range of options or elements for using the resources. The logical configuration data includes resource requirement information that defines certain resources of the computer which are necessary for proper operation of the particular device with the computer. For example, resource requirement information for a modem may define a resource requirement for an interrupt within the range of interrupts 7-12. The logical configuration data also includes resource dependency information, which defines a particular combination of resource elements that are necessary for device operation. For a modem, typical resource dependency information may define the combination of interrupt IRQ4 with I/O3F8 (COM PORT 2).

The above-described steps of the identification process are repeated for each of the remaining devices connected to the system bus to permit the collection of device information from all connected devices. In the event that a device itself is implemented as a system bus, it may be necessary to identify device drivers, allocate resources, and load the identified device drivers prior to identifying any devices connected to this new system bus. For example, these tasks are typically completed prior to identifying a device connected to the PCMCIA bus which, in turn, is connected to an integrated expansion bus of the computer's system board, such as an ISA bus.

To assign the device identification code, the identification code can be accessed by reading the identification code from a memory storage device, such as read only memory (ROM) or a register, which is typically mounted on the interface board for the device. The system bus code is subsequently added to the identification code to complete the formation of the device identification code. The device identification code is thereafter typically stored within computer memory to support the configuration process.

Similarly, the logical configuration data can be retrieved from the particular device by reading the logical configuration data from the memory storage device for that device. The logical configuration data is thereafter stored within the computer memory and is associated with the device identification code for the particular device. In the event that the logical configuration data is not available from the particular device, at least a portion of the logical configuration data often can be retrieved from a selected file of the computer operating system, such as a configuration file, e.g., an .INF file.

The resource allocation process is supported by arbitrators that operate to determine the assignment of resource elements to the devices of the computer. An arbitrator is assigned to each resource of the computer and is responsive to the resource requirement information and resource dependency information related to its resource to produce a conflict-free allocation of the resource elements. The arbitrator for a selected resource is programmed to recognize the characteristics of its resource. For example, the arbitrator for a interrupt resource of a conventional personal computer recognizes that this resource includes 16 interrupt elements.

An arbitrator includes an analysis element that is responsive to a possible configuration which defines the set of resource elements that are appropriate for operating the devices with the computer. In response, the analysis element determines whether a particular resource element for a selected device is available for use by the selected device. The arbitrator also includes an assignment element for assigning the particular resource element for use by the selected device in response to determining that the particular resource element is available for use by the selected device.

Focusing upon yet another aspect of the present invention, a method is provided for obtaining a device driver to enable a device to communicate with a computer. The computer includes a database containing a set of records. Each record contains both a device identification field for storing the identification code of a primary device and a compatible device identification field for storing identification codes for compatible devices and at least one type of compatible device-related data.

Reviewing the data structure for a database record, the device identification field permits the recording of an identification code that identifies a primary device for operation with the computer. Likewise, the compatible device identification field permits the recording of both an identification code that identifies the primary device and identification codes that identify compatible devices. If the compatible device identification field contains an entry for the primary device, then a device driver specifically intended to support the computer operations of that primary device is available on the computer. Likewise, compatible device drivers are available to support computer operations for both the primary device and other associated compatible devices if the compatible device identification field contains identification codes for compatible devices.

As an option, the compatible device identification field also permits the recording of priority data to permit a further distinction between the devices represented by the compatible device identification codes. The priority data supports the selection for a device driver of one of the compatible devices over another compatible device driver based upon the assigned rankings of the compatible devices. For example, the priority data can include a preferred use ranking or priority assigned by the vendors for the compatible devices. The compatible device having the highest priority ranking is typically selected for installation.

To obtain the device driver for a certain primary device, the computer database is searched to locate a selected record which is associated with that device. The identification code for this device is used as the entry key for the database because it identifies the desired device. Upon locating the selected record, the compatible device identification field is reviewed to determine if this field contains the identification code for the certain primary device.

If the identification code for the certain primary device is located within the compatible device identification field of the selected record, then the corresponding primary device driver is selected for use with the computer. Upon identifying the proper device driver. the task of retrieving the desired device driver from its storage location is controlled by the operating system in a conventional manner. The identified primary device driver often can be retrieved from the mass memory storage device of the computer.

However, in the event that the compatible device identification field does not contain the identification code for this primary device, then this field is examined to determine if it contains one or more of the identification codes for compatible devices. If so, then the compatible device having the highest priority is selected and the corresponding device driver is retrieved from the computer.

In the event that the compatible device identification field does not contain an identification code for a compatible device, then the computer supplies to the user an indication of the absence of the necessary driver for associated device. This indication can be a text-based or a combined text/graphics message, which is displayed by the computer monitor or supplied to a printer, or an audio prompt or statement.

In furtherance of these principles, it is an object of the present invention to provide a system for configuring devices of a computer.

It is a further object of the present invention to provide a system for configuring a new device connected to a computer.

It is a further object of the present invention to provide a system for identifying the devices connected to a computer.

It is a further object of the present invention to provide a system that identifies the resource usage and system resource options for a device by obtaining such information from the device.

It is a further object of the present invention to provide a system that optimally allocates resources for use by the devices of the computer.

It is a further object of the present invention to provide a system that identifies the devices of the computer, determines a working configuration for the devices, and loads the appropriate device drivers.

It is a further object of the present invention to provide a system that accommodates seamless-dynamic configuration of resources by enabling the configuration of devices in response to docking a mobile computer to a base station, removing the mobile computer from the base station, adding a new device to a computer, or removing a device from the computer.

It is a further object of the present invention to supply remote and local access to information directed to the present configuration of the computer and the types of devices connected to the computer.

It is a further object of the present invention to provide a system for configuring a network system.

It is a further object of the present invention to provide a system for configuring a network adapter of a computer.

That the present invention accomplishes these objects and offers the above-described advantages will be apparent to those skilled in the art from the following description, the appended claims, and the accompanying drawings.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is an overall block diagram of a computer in which the preferred embodiment of the present invention is operative.

FIG. 2 is a block diagram that illustrates the preferred embodiment of the present invention.

FIG. 3 is a flow chart diagram that illustrates the steps of a method for configuring the devices of a computer.

FIGS. 4A-C are flow chart diagrams that illustrate the preferred steps of a method for configuring the devices of a computer in accordance with the preferred embodiment of the present invention.

FIG. 5 is a flow chart diagram that illustrates the preferred steps for a method for obtaining a compatible device driver for use with a device of the computer.

FIG. 6 is a block diagram that illustrates the components of the preferred embodiment of the present invention.

FIGS. 7A and 7B are diagrams that illustrate one of the components of the preferred embodiment of the present invention, specifically a hardware tree comprising device nodes for storing device-related information for the present configuration of the computer.

FIG. 8 is a diagram that illustrates one of the components of the preferred embodiment of the present invention, specifically a registry for storing archival device-related information for the computer.

FIG. 9 is a block diagram that illustrates the elements of a component of the preferred embodiment of the present invention, specifically an enumerator.

FIG. 10 is a flow chart diagram that illustrates the preferred steps for a method for enumerating devices of a computer.

FIGS. 11A and 11B are flow chart diagrams that illustrate the preferred steps for responding to dynamic events that affect the operating state of a computer.

FIG. 12 is a block diagram that illustrates the elements of a component of the preferred embodiment of the present invention, specifically an arbitrator.

FIG. 13 is a flow chart diagram that illustrates the preferred steps for a method for assigning a resource for conflict-free use by a device of a computer.

FIG. 14 is an overall block diagram of a network system in which the preferred embodiment of the present invention is operative.

FIG. 15 is a block diagram of a hierarchical architecture for hardware and software components of a network system.

FIG. 16 is a flow chart diagram that illustrates the steps of a method for configuring the network adapter of a computer.

FIG. 17 is a diagram that illustrates entries stored within a registry for the network architecture shown in FIG. 15.

FIGS. 18A and 18B are diagrams that illustrate device nodes of a hardware tree for the network architecture shown in FIG. 15.

FIGS. 19A and 19B are flow chart diagrams that illustrate the preferred steps of a method for configuring a network adapter of a computer.

DETAILED DESCRIPTION

To overcome the frustration of users with the present complicated and technical configuration processes for personal computers, the present invention provides a system for automatically configuring a peripheral device or an add-on type adapter board for use with a base or mobile computer. The present invention enables a user to simply connect a new device to the computer, power the computer, and have the device properly work with the computer without user intervention. To provide this capability, the present invention determines the optimal configuration for the resources and enables the devices and the application programs to fully utilize the available resources. This can be accomplished for numerous computer bus architectures and types of devices.

The detailed description which follows is presented largely in terms of algorithms and symbolic representations of operations by conventional computer components, including a processor and memory storage devices. These algorithmic descriptions and symbolic representations are the means used by those skilled in the art to most effectively convey the substance of their work to others skilled in the art.

An algorithm is generally conceived to be a self-consistent sequence of steps leading to a desired result These steps generally require physical manipulations of physical quantities. Usually, though not necessarily, these quantities take the form of electrical or magnetic signals capable of being stored, transferred, combined, compared, or otherwise manipulated. It is convenient to refer to these signals as bits, values, elements, symbols, characters, terms, numbers, records, files or the like. It will be appreciated that all of these terms, as well as similar terms. are associated with appropriate physical quantities and are merely convenient labels applied to these quantities.

Automated Configuration System

FIG. 1 shows a block diagram of the preferred operating environment, a computer 8, for the preferred embodiment of the present invention. The present invention is based upon computer-implemented processes that can be embodied in one or more computer programs for a data processing system, such as the computer 8. to carry out the methods and functions described herein. This computer-implemented process operates upon electrical or other physical signals to generate the desired physical results. Referring now to FIG. 1, the computer 8 runs an operating system 10 that operates with a central processing unit (CPU) 12, resources 14, system busses 18, devices 20, and a computer control system 21. The resources 14 include memory addresses for a memory 22, interrupts 24, direct memory access (DMA) channels 26, and input/output (I/O) ports 28. The system busses 18 typically include a local bus 13, an integrated bus 15, such as a system-level expansion bus, and at least one interface bus 17. The computer 8 represents a typical configuration for a conventional personal computer and it will be understood that the present invention is not limited to operations with the disclosed configuration for the computer 8.

The operating system 10 comprises a set of computer programs that control the internal functions of the computer g, thereby allowing the computer 8 to run application software (not shown). For the preferred embodiment, the operating system 10 is a graphic-based operating system, such as the “WINDOWS” operating system available from the assignee for this application, Microsoft Corporation, Redmond, Wa. The operating system 10 is preferably installed on a mass memory storage device, such as a fixed disk drive, of the computer 8. During computer operations, the operating system 10 is also allated a portion of the memory 22 to support operations with the other components of the computer 8.

The CPU 12 is typically implemented as a microprocessor, such as the models 80386 or 80486 that are available from Intel corporation, Santa Clara, Calif. The CPU 12 operates in combination with computer software, such as the operating system 10 and application programs, to control the operations of the computer 8. One or more of the system busses 18 support communications of control, address, and data signals between the CPU 12 and the remaining components of the computer 8.

The resources 14 represent the resources of a conventional personal computer, such as the computer 8. The memory 22 is typically implemented by dynamic or volatile memory modules, such as random access memory (RAM), and static or nonvolatile memory modules, such as read only memory (ROM) units. The memory 22 preferably includes a conventional memory, which is the first 1024 kilobytes of dynamic memory in a personal computer, and an extended memory that extends above the 1024 kilobytes range. The interrupts 24, also referred to as the interrupt request lines, are signal paths within the computer 8 that carry signals informing the recipient that the sender is ready to transmit or to receive data. The DMA channels 26 enable the devices 20 or a computer program running on the computer 8 to access the memory 22 without involvement by the CPU 12, thereby supporting relatively fast data transfers. The I/O ports 28 represent ports used by the devices 20, such as peripheral devices or adapter boards, to communicate with the CPU 12.

The computer database 16 provides a central location for storage of archival information that supports the configuration of the devices 20. Specifically, the computer database 16 stores general system hardware and software parameters, as will be described in more detail below with respect to FIG. 8. The computer database 16 is preferably implemented by nonvolatile memory, such as a fixed disk or another type of mass storage memory device.

Each system bus 18 can be viewed as a “parent” capable of having “children” because a system bus provides a mechanism for connecting devices 20 to the computer 8. The system busses 18 typically supply the signal paths for the exchange of data, control signals, and addressing information among the components of the computer 8 and peripheral components, including the devices 20. The system busses 18 can be implemented as various bus architectures, such as the Industry Standard Architecture (ISA), Micro Channel Architecture (MCA), and Extended Industry Standard Architecture (EISA) standards, as well as Personal Computer Memory Card International Association (PCMCIA), Small Computer Systems Interface (SCSI), Personal Computer Interface (PCI), Enhanced Capabilities Parallel (ECP), Vesa Local Bus (VL), Integrated Drive Electronics (IDE), and other bus standards. The system busses 18 also can include local or personal computer (PC) busses, serial busses, and parallel busses. However, it will be understood that the present invention is not limited to operation with the above-described busses and that these busses are listed as representative of existing bus architectures.

The system busses 18 include the local bus 13, the integrated bus 15, and a pair of interface busses 17 and 17′. The integrated bus 15 is preferably an integrated or “fixed” expansion-type bus that enables the direct connection of peripheral devices or adapter boards to the computer 8. In contrast, the interface busses 17 and 17′ are typically supplied by vendors as separate accessory or optional components that can be attached to the computer 8 via the local bus 13 or the integrated bus 15. Nevertheless, both the interface busses 17 and 17′ permit the connection of additional devices to the computer 8.

For the representative computing environment shown in FIG. 1, the integrated bus 15 is implemented as an ISA bus and is connected to the local bus 13 on the system board of the computer 8. In addition, the interface busses 17 and 17′ are respectively implemented as a SCSI bus and a PCMCIA bus. In particular, the SCSI bus is connected to the local bus 13 and the PCMCIA bus is connected to the integrated bus 15.

The devices 20, which are connected to the system busses 18, represent the logical functions of components that can be connected to a personal computer. The devices 20 include components typically located on or connected to a system board of a personal computer, including system-level devices, such as 10 controllers (fixed and flexible disk controllers), keyboard controller, serial and parallel controllers, system timer, display controller, programmable interrupt controller (PIC), and DMA controller. The devices 20 further include the functional devices for peripheral adapter boards and interface boards. Thus, for the representative computing environment shown in FIG. 1, the devices 20 include system-level devices (not shown), a modem card, and a network card.

A device 20 also can be implemented as a system bus 18 that is connected to another system bus. For example, in the computer 8, the PCMCIA bus is connected to the ISA bus and is capable of supplying a connection to the computer 8 for other devices. Thus, the PCMCIA bus represents both a system bus 18 and a device 20 within the computer 8. Likewise, both the ISA bus and the SCSI bus may be viewed as a system bus 18 and a device 20. Following the earlier analogy to “parent” and “child” components, it will be appreciated that a system bus 18 may be both a “parent” and a “child” within the preferred operating environment of the computer 8.

Although each of the devices 20 are shown in FIG. 1 as separate physical components, it will be understood that a computer component can contain more than one function and, accordingly, that component can contain more than one of the devices 20. Thus, it will be useful to consider the device 20 as a logical device rather than as a physical device. It sill be understood that the devices 20 supply the building blocks that are required to harness the computing power offered by the CPU 12 and the resources 14.

With the exception of system-level devices, which are typically supplied as part of the system board of the computer 8. a device 20 can be connected to a memory storage device 29, such as a ROM or a register, for storing information about the associated device 20. The memory storage device 29 is useful for storing device-related information that supports the configuration of the devices within the computer 8. This device information typically includes a string of characters for uniquely identifying a corresponding device and resource usage data. For devices on adapter boards, the memory storage device 29 is preferably mounted on the board itself.

The inventors believe that the actual implementation of the memory storage device 29 can be any type of circuit or component that allows the device information to be accessed to support configuration operations. Typical data storage components include ROMs, registers, and other conventional memory components. Furthermore, the device-related information also can be “stored” by constructing circuitry that represents a “hard-wired” version of such information. Device information can be stored in a device-dependent fashion. Accordingly, it will be understood that the memory storage device 29 is not limited to the above-described implementations.

The computer control system 21 conducts initialization and test functions, as well as device configuration functions, when the computer 8 is first powered or “booted.” Upon booting the computer 8, one or more start-up programs begin to run to implement necessary initialization and test functions. These start-up programs may be implemented as stand-alone programs or are integrated to function within the framework of the operating system 10.

The start-up programs typically include a basic input/output system (BIOS) program and a power-on self-test (POST) program. The BIOS program supplies device-level control or support services for the primary input/output devices of the computer during the boot “initialization” process. Furthermore, after boot, the BIOS program accepts requests from application programs or the operating system running on the computer and performs input/output services as requested by those programs. The POST program conducts a sequence of tests for certain system-level devices and resources, including memory, to verify the proper operation of the computer components that are required to be active upon completion of the boot process. The programs associated with the computer control system 21 are preferably stored in ROM located within the computer 8, typically on the computer motherboard. The functions and operations of conventional BIOS and POST programs are well known and will not be further described herein. However, as described in more detail below, the computer control system 21 preferably includes a modified BIOS program that is further capable of (1) configuring the boot-level devices of the computer 8 and, if required, (2) detecting the insertion or removal of the computer 8 from a docking station or an expansion system. This modified BIOS program can be viewed as a type of system bus because it supplies connections to the system-level devices on the motherboard to support the configuration of such devices.

When viewed collectively, the CPU 12, the resources 14, a fixed disk including the computer database 16, the system busses 18, and the devices 20 represent the hardware components for a typical personal computer as embodied by the computer 8. The devices 20, which are connected to system busses 18 that are organized in a hierarchical manner, perform their respective functions by operating with the resources 14. Nevertheless, with the exception of certain types of the peripheral devices or adapter boards, the typical user is rarely exposed to the technical aspects of computer operations. In view of the relative technical complexity of the typical personal computer, it will be appreciated that there is a need for a system for configuring the devices of a personal computer without substantial support by the user. The inventors' solution for this problem is a system that permits a user to simply connect or attach a desired device to a computer, power-on the computer, and thereafter use the function associated with the device. This configuration system is supported by the hardware components of its computing environment and the computer-implemented processes of the operating system 10 and the computer control system 21.

FIG. 2 is a block diagram that illustrates the basic building blocks for the preferred embodiment of the configuration system. Referring now to FIGS. 1 and 2, the configuration system is useful for configuring the computer 8 to insure that the devices 20 have conflict-free access to the resources 14. Configuration logic 30, which can be implemented as a portion of the operating system 10, controls the configuration tasks. Specifically, the configuration logic 30 is supported by the operating system 10, the computer control system 21, and the processing and storage functions offered by the computer 8.

In response to an event causing an asynchronous change in the operating state of the computer 8, the configuration logic 30 operates to collect device information from each of the devices 20. For devices that have been designed to support the preferred operating system, this device information can be accessed by reading at least a portion of the data from a data storage mechanism associated with the device 20, such as the memory storage device 29. The configuration logic 30 thereafter allocates the resources 14 for the devices 20 in response to the collected device information. This prevents a conflicting use of the resources 14 by the devices 20 within the computer 8.

To collect device information from a selected device 20 on one of the system busses 18, the configuration logic 30 includes a detection module 31 for detecting a selected device on that bus and a collection module 32 for collecting device information from the detected device. Each system bus 18 in the computer 8 is preferably represented by a combination formed by a detection module 31 and a collection module 32. This combination defines the enumeration function of a component of the operating system 10 that will be described in more detail below with respect to FIG. 6, specifically an enumerator.

A driver identification module 33 responds to the device information by identifying a device driver for each of the devices 20 that supplied device information to the collection module 32. The collected device information is then analyzed by an arbitration module 34 to determine whether the selected device requires a potential conflicting use of the resources 14.

The arbitration module 34 assigns elements of the resources 14 by searching for available resource elements. As required, the arbitration module 34 resolves any potential conflicting use of an element of the resources 14 to enable the conflict-free allocation of a resource element to the selected device 20. Each resource 14 can be represented by a self-contained component of the arbitration module 34 to permit the efficient addition of arbitration capabilities for new resources. A driver loading module 35 thereafter loads the identified device drivers for use by the devices 20 in response to the allocation of the necessary elements of the resources 14.

FIG. 3 generally shows the steps for a method for configuring the devices 20 for operation with the computer 8. Turning now to FIGS. 1 and 3, the computer-implemented process is started and device information is collected at step 37 for each of the devices 20. For each device 20, the device information includes identity data for uniquely identifying the corresponding device and resource allocation data for defining the resource requirements of the particular device. This device information is preferably associated with or otherwise linked with information for the corresponding system bus 18. The resulting product of this data collection process can be viewed as an inventory of the devices 20 connected to the system bus 18 of the computer 8.

For the devices that are designed to take advantage of the present inventive concept, at least a portion of the device information can be acquired by accessing the memory storage device 29. However. certain system-level components and existing “legacy” boards containing devices 20 may not include a memory storage device 29 for storing such device-level information. In this event, the device-level information is preferably acquired from other sources, such as the BIOS program of the computer control system 21 or configuration files of the operating system 10. For the legacy devices, certain device-level information can also be acquired by examining the signature-like responses output by these devices in response to command signals supplied to the I/O ports 28.

A device driver is thereafter obtained at step 38 for each of the devices 20 in response to the device information. At step 39, the resources 14, which are used by the devices 20 during computing operations, are allocated ibased upon the device information. Resource allocation is preferably an iterative routine that attempts to identify and resolve potential resource conflicts prior to an actual conflicting use of the resources 14 by the devices 20 during operation of the computer 8. In response to this allocation of the resources 14, the device driver for each of the devices is loaded at step 40 and the devices 20 are subsequently activated for operation with the computer 8, thereby terminating this configuration process.

Device information is preferably acquired for each of the devices 20, including all devices 20 supported by peripheral devices, add-on type adapter boards, system-level devices, and certain system busses. However, in the event that one of the devices 20 itself is implemented as a system bus, it may be necessary to complete the configuration tasks for the identified devices 20 connected to the system bus 18 prior to detecting any devices on the newly identified system bus. These tasks include identifying device drivers, allocating resources, and loading identified device drivers for the remaining devices 20 on the first system bus prior to identifying any of the devices connected to this newly identified second system bus.

For the computer 8, the steps shown in FIG. 3 are preferably first conducted for the devices 20 on the integrated bus 15 and thereafter repeated to permit the identification of the additional devices connected to the interface bus 17′. This enables the devices 20 connected to the “parent” component represented by the ISA bus to be configured prior to the devices 20 on the “child” component of the PCMCIA bus. It will be understood that this type of configuration sequence is defined by the connection of second system bus (the PCMCIA bus) to a first system bus (the ISA bus).

In this manner, the devices 20 of the computer 8 are identified and associated with each of the system busses 18. In addition, the resources 14 are efficiently allocated based upon the device information, and the device drivers are assigned and loaded to enable the operations of the devices 20 with the computer 8. It will be understood that the proper configuration of the computer 8 is necessary for the devices 20 to use the resources 14 of the computer 8 and to communicate with the application programs (not shown) running on the computer 8. Accordingly, the computer 8 is typically configured prior to using the devices 20 for the desired computing functions.

Although it is desirable to configure all of the devices 20 during the power-up or boot processes, particularly prior to completing the test and initialization routines of the computer control system 21, many resource conflicts cannot be fully resolved without complete knowledge of all resource requirements for the devices 20. Nevertheless, the preferred system supports the configuration process during the computer start-up sequence for a limited set of the devices 20, specifically those boot-level devices that are required to “come-up” active during the boot process. Thus. this pre-boot configuration process is completed for the “fixed” system-level devices on the computer's system board, which is also described as a motherboard. Likewise, the pre-boot configuration process is completed for the set of devices 20 that are connected to integrated expansion board, specifically the integrated bus 15, and are required for boot-level operations. The remaining devices 20, which also may require resource allocation, are preferably configured only after the computer 8 has completed the boot process.

FIGS. 4A-C are flow chart diagrams illustrating the preferred steps of a method for configuring the devices of a computer. Referring now to FIGS. 4A-C, which are collectively described herein as FIG. 4, and to FIG. 1, the configuration process is initiated in step 41 by powering-up the computer 8.

In step 42, certain devices 20 on the system board, which are also described as system-level devices, are configured in response to powering the computer 8. These system-level devices. which are configured based upon power-on default configuration settings, typically include I/O interfaces, the keyboard controller, the serial and parallel interfaces, the display controller, the system timer, the PIC, and the DMA controller. It will be appreciated that many of these components are mounted on the motherboard of a conventional personal computer. The system-level devices are preferably configured based upon default configuration parameters stored in the computer control system 21. The default configuration parameters for the system-level devices in the computer 8 are defined by the resource requirements and resource dependencies for such devices.

The preferred configuration process is based upon the collection of device-specific information from each of the devices 20 of the computer 8 to isupport the allocation of the resources 14 to those connected devices. Thus, still referring to FIGS. 1 and 4, the preferred configuration process continues for the devices 20 that are connected to the system-level expansion bus of the computer 8, specifically the integrated bus 15. In step 44, the integrated bus 15 is selected and an enumerator (not shown) is loaded for the ISA bus. In subsequent steps, each of the devices 20 connected to the ISA bus of the computer 8 is examined to obtain device information.

In step 46, one of the devices 20 on the selected ISA bus is detected to enable the communication of device information from the detected device 20. For the ISA bus, the detected device is isolated from the remaining devices on the bus to permit interference-free communications with that device. Nevertheless, it will be appreciated that other types of system busses do not require isolation of the detected device to enable communications with that device. The preferred system for detecting the interface boards associated with the devices 20, isolating a particular interface board, and collecting device information is described in a related application, U.S. patent application Ser. No. 08/023,689, filed Feb. 25, 1993, entitled “System and Method for Computer Interface Board Identification,” which is assigned to the assignee for this application and hereby incorporated by reference. The system described in the referenced application automatically determines which interface boards are connected to a computer bus and automatically assigns parameter selections to ensure proper operation of the boards within the computer.

At step 48, the detected device 20 is assigned a device identification code that preferably identifies the particular device as a certain device type connected to a selected bus, in this case, the integrated bus 15. The device identification code comprises an identification code and a system bus code. The identification code comprises a data string which uniquely define the corresponding device. The identification code can include characters defined by the well known American Standard Code for Information Interchange (ASCII) or a combination of ASCII and non-ASCII data bytes. Similarly, the system bus code, which also can be implemented as a string of ASCII characters or a combination or ASCII and non-ASCII data, uniquely identifies a corresponding system bus. The identification code is typically supplied by the device 20, whereas the system bus code is associated with the system bus 18 and is generated external to the device 20. For example, a modem is preferably assigned an identification code that is different from the identification code for a printer, and different architecture expansion busses, such as ISA and MCA busses, are preassigned different system bus codes. Thus. the identification code defines the detected device and the system bus code defines the selected system bus that supplies the connection for the detected device.

For the preferred embodiment, the identification code is used to identify the class or the type of the device 20. The vendor of the peripheral device associated with the device 20 typically defines the unique identification code for that device. Nevertheless, it will be appreciated that the identification code does not need to contain any information about the class or the type of the device 20. Indeed, the only requirement for the device identification code is that the data string formed by this combination of the system bus code and the identification code should be consistently used each time the computer 8 boots to uniquely identify the particular device 20 on the selected bus 18.

The collection of device information continues at step 50. Specifically, logical configuration data is obtained for the detected device 20. The logical configuration data is preferably logically linked to the device identification code for the particular device 20. This device information is preferably stored in nonvolatile memory that is allocated for such use by the operating system 10. In addition, if the particular device 20 represents a newly installed device for the computer 8, then the device information is also stored within the computer database 16 to maintain an archival record of all of the devices 20 that have been installed for operation with the computer 8.

The logical configuration data defines the set of resources 14 necessary for operation of the particular device 20 with the computer 8. Specifically, the logical configuration data comprises both resource requirement information and resource dependency information. The resource requirement information defines certain resources 14 which are necessary for operation of the particular device 20. It will be appreciated that computer resources, such as the resources 14, include multiple resource options or elements, such as allocated memory ranges and a predefined set of interrupts, DMA channels, and I/O ports. Thus, the resource requirement information preferably defines a range of elements for each of the resources 14 required for the operation of the associated device. For example, a printer may require a communications port within a range of the I/O ports 28. In contrast, the resource dependency information defines a particular combination of resource elements which are necessary for the operation of the particular device 20. For example, the resource dependency information for a modem may define a specific combination of an interrupt and an I/O port for the operation of that device.

Upon completing the collection of device information from the detected device 20, an inquiry is conducted at step 52 to determine whether device information has been obtained from all of the devices 20 on selected bus, in this case, the integrated bus 15. If the answer is negative, the “NO” branch is followed to the step 46 to continue the collection of device information from the remaining devices 20 on the integrated bus 15. In contrast, the “YES” branch is followed to the step 54 if device information has been acquired from all such devices 20. At this point, the device identity data and resource usage information have been obtained for each device 20 that either is a system-level device or is directly connected to the integrated bus 15.

In step 54, an inquiry is conducted to identify the subset of the devices 20 that must be active upon completion of the boot process. For the devices 20 that do not require a default-type configuration during the power-up sequence, the “NO” branch is followed to the step 56 and those devices preferably remain inactive during the power-up sequences. In contrast, the “YES” branch is followed from the step 54 to the step 58 for the devices 20 that must be activated during the boot process. Based upon this inventory of the identified devices 20 requiring activation during the boot process, a boot-level device driver for each of those devices is obtained in step 58 to enable communications between the boot-level devices and the computer 8. These boot-level devices typically include the system-level devices 20 on the system board of the computer 8 and certain adapter boards connected to the integrated bus 15, such as a display controller or a mass memory storage device controller, i.e., a fixed disk controller.

In step 60, an inquiry is conducted to determine if the resources 14 required by the set of identified devices 20 requiring enablement for the boot process are conflict-free. If so, the “YES” branch is followed to step 64. The resources required by these devices 20 are allocated during the step 64 and the required device drivers are subsequently loaded to permit boot-level operations. Alternatively, if the response to the inquiry in step 60 is negative, then the “NO” branch is followed to step 62 and the user is preferably supplied an error message based upon the detection of a resource conflict during the boot process. In response, the user may be required to power down the computer and manually reconfigure the computer 8. However, it is not anticipated that a resource conflict for boot-level devices will be a common occurrence because the configurations for many of the boot-level devices mounted on the system board are typically pre-defined to be conflict-free by the computer vendor.

The above-described configuration steps 42-64 are preferably ii supported by software routines for the modified BIOS program of the computer control system 21. The modified BIOS program supports the identification of each of the boot-level devices, including system-level devices and the boot-level devices on the integrated bus 15, and stores device-related information within computer memory to support the configuration tasks for those devices. With the exception of the system-level devices, the configuration support supplied by the modified BIOS program concludes after the POST process is completed. Specifically, after POST, the control of the configuration process for all remaining devices 20 is preferably maintained by the operating system 10 rather than by the computer control system 21.

Upon completion of this portion of the configuration process, the conventional POST and BOOT routines are then conducted for the computer 8 during the steps 66 and 68, respectively. As a result of loading the operating system 10, selected configuration files of the operating system 10, such as Config.Sys and the Autoexec.Bat files, are processed by the computer 8. The Config.Sys file is a system configuration file that contains parameters which determine how the computer will operate. The Autoexec.Bat file supports user customization of computer operations, particularly the handling of application programs. The operations of both Config.Sys and Autoexec.Bat files for conventional operating systems are well known and will not be described herein.

Although FIG. 4 shows a specific sequence for the POST and BOOT routines, it will be understood that the configuration process can be adapted to operate with a different sequence of those routines. For example, at least a portion of the task operations of the POST routine can be completed after power-up and prior to the configuration of system-level devices in step 42.

Unlike the system board devices and the boot-level devices connected to the integrated bus 15, which are respectively configured during steps 42 and 64, the remaining devices 20 connected to the integrated bus 15 are configured only after the boot operations for the computer 8 have been completed. However, the configuration operations for the nonboot-level devices on the integrated bus 15 are supported by the collection of device information that occurred prior to the BOOT process of step 68. In particular, this configuration process is supported by the current inventory of both the system board devices and the set of devices 20 connected to the integrated bus 15.

At step 70, the device drivers for this set of nonboot-level devices are identified in response to the device information collected during the preboot operation. The device drivers are typically identified by accessing corresponding device-related information that is stored in the computer database 16 or by accessing a predefined file of the operating system 10. The process for identifying and obtaining the device drivers will be described in more detail below with respect to FIG. 5.

The device information collected during the preboot operation further supports the allocation and the assignment of the resources 14 required by the nonboot-level devices on the integrated bus 15. In step 72, the resource requirements and dependencies for each of the nonboot-level devices 20 on the integrated system bus 15 are compared to the available resources 14. This comparison permits a determination of whether a potential resource conflict exists. In an iterative fashion, potential resource conflicts are arbitrated and resolved prior to resource allocation. In step 74, the resources 14 are allocated to the nonboot-level devices 20 based upon the arbitration results of the step 72 and those devices are configured in step 76. In view of the allocated resources, the identified device drivers are loaded in step 78 and the devices are enabled for operation with the computer 8. This arbitration process is described in more detail below with respect to FIG. 13.

For the system board devices and the set of devices directly connected to the integrated bus 15, device information has now been collected and stored in volatile computer memory and, as required for newly installed devices, in the nonvolatile memory of the computer database 16. The device information for the devices 20 on the integrated bus 15 may identify one or more of the devices as another system bus 18 capable of supporting other connected devices 20. Device information has not yet been collected for the “children” devices of each system bus 18 connected to the integrated bus 15. Nevertheless, for the preferred embodiment the tasks of identifying device drivers, arbitrating and allocating the resources 14, and loading the identified device drivers for the set of nonboot-level devices 20 on the integrated bus 15 enable the subsequent collection of device information from these children devices. Thus, at step 80, an inquiry is conducted to determine whether any of the devices 20 on the selected integrated bus 15 are operable as system busses. If not, the “NO” branch is followed to step 82 and the automated configuration operation for the computer 8 is completed. In contrast if another system bus is connected to the computer 8, then the “YES” branch is followed to step 84 to continue the data collection process.

Referring still to FIGS. 1 and 4, in step 84, another one of the system busses 18 is selected to support the configuration of the set of the devices 20 connected to that selected bus. For the illustrative example of FIG. 1, the interface bus 17′ is selected and the enumerator for that bus is loaded. One of the devices 20 on the interface bus 17 is subsequently detected in step 86. At step 88, the detected device 20 is assigned a device identification code comprising the identification code for the detected device and the system bus code for the interface bus 17′. Likewise, logical configuration data is obtained for the detected device 20 during the step 90 to define the resources 14 necessary for operation of the device.

Upon completing collection of device information from the detected device 20, an inquiry is conducted at step 92 to determine whether device information has been obtained from all of the devices connected to the interface bus 17′. If the answer is negative, the “NO” branch is followed to the step 86 to continue the collection of device information from those remaining devices 20. In contrast, the “YES” branch is followed to the step 70 to enable the sequence of identifying device drivers, arbitrating and allocating the resources 14, and loading the identified device drivers for the detected devices 20 of the interface bus 17′. This process will be repeated until all of the system busses 18 within the computer 8 are detected.

It will be understood that the device information collection process has now been completed for the existing devices 20 of the computer 8. Specifically, the device identification code and the logical configuration information have been collected from each of the devices 20. This device information is preferably stored in the computer memory 22 to support any additional configuration operations that are necessitated by another asynchronous event affecting the operating state of the computer 8.

It will be appreciated that existing personal computers generally do not include a modified BIOS program to implement the specific sequence defined by the steps 42 through steps 64 for the configuration process shown in FIG. 4. Accordingly, for computers with a conventional BIOS program, the system board devices are configured by the BIOS program and the initialization processes performed by the POST and BOOT routines are conducted in a known manner in response to powering the computer. After the completion of the boot sequences, an embodiment of the present invention supports the automated configuration of the remaining devices connected to this computer.

Specifically, upon booting the computer, this postboot configuration process for a conventional computer starts at step 84 by selecting one of the system busses 18. However, unlike the previously-described configuration operation, the integrated bus 15 is selected only after the completion of the BOOT routine. In this manner, the sequence of tasks starting at step 84 of FIG. 4 are completed to identify and characterize the existing devices 20 of the computer 8, to identify the associated device drivers, to allocate the resources 14, and to load the device drivers.

Referring now to FIG. 1, a device driver for an associated device 20 can be obtained from one of several alternative sources of the computer 8, including the operating system 10, the device 20 itself, or indirectly from the user via a disk containing the device driver. The preferred operating system 10 includes one or more files that contain device drivers for supporting the most commonly used peripheral devices and add-on type adapter boards. Similarly, the memory storage device 29 located on certain adapter boards also can be used for storing device drivers for operating the associated device with a personal computer. In addition, conventional peripheral devices and adapter boards are often times supplied by vendors with one or more computer disks containing installation software programs and supporting software programs, including device drivers. Upon loading a device driver for use by the computer 8, the device driver is typically stored on the computer's mass storage memory device, such as a fixed disk.

To maintain an archival record for each device 20 installed on the computer 8, the device information for a particular device is stored within a corresponding record of the computer database 16. Thus, the central database 16 preferably maintains a set of records containing a listing of the identification codes for the devices 20 of the computer 8 and a listing of compatible device information. Each record contains a device identification field for storing an identification code associated with a certain primary device and a compatible device identification field for storing identification codes associated with both a primary device and corresponding compatible devices. A compatible device is a device that performs the same functions to achieve the same results in the same manner as the primary device. For example, a first modem card may be compatible with a second modem card because both cards perform the same function and conform to an industry standard for modem communications.

The compatible device identification field also permits the recording of priority data to permit a further distinction between the devices compatible with a primary device. For example, this priority data can include vendor-assigned ranking data and is supplied by ranking the identification codes for compatible devices in the preferred order of use. In this manner, priority data is supplied by the order in which the identification codes within the compatible device identification field are listed.

Table 1 shows a several of the data fields for a record of the computer database 16. The first field, which is labeled “Device Identification”, contains identification codes for the devices 20. The second field, which is labeled “Compatible Device Identification”, contains identification codes and related information for compatible devices. This information represents at least a portion of the data stored in typical record in the computer database 16.

TABLE 1 Device Identification Compatible Device Identification Identification Code Identification Code Audio B3 Audio B3 Sblast Windows Sound

As shown in Table 1, each identification code in the device identification field has one or more corresponding entries in the compatible device identification field, namely entries for identification codes and installation dates. A primary device is identified in the device identification field by the identification code “AudioB3”. The compatible device identification field also contains the same identification code. When the device identification field and the compatible device identification field contain the same identification code, a device driver specifically designed for use with the identified device is available on the computer 8. This type of device driver is also described as a primary device driver. Thus, for the example shown in Table 1, the primary device driver is available to support the operations of the particular device 20 identified by the entry “Audio B3” in the device identification field.

The primary device driver, if available, is preferably obtained to support the operations of the corresponding device 20. If the primary device driver is not available, then the compatible device identification field is preferably searched for an entry representing a compatible device. If at least one compatible device entry is present, then a device driver that is compatible with the primary device is available on the computer 8. It is well known that a device driver may support the operations of both the intended primary device and one or more other compatible devices sharing similar operating characteristics with the primary device. Thus, a “compatible” device driver, if available, may be used to enable communications of the particular device 20 with the computer 8 in the absence of the primary device driver for that particular device. It will be understood that the primary device driver is intended to support the computer operations of the primary device, whereas each compatible device driver supports computer operations for the primary device and other compatible devices.

The compatible device identification field in Table 1 further shows a pair of identification codes associated with devices that are compatible with the “AudioB3” device, namely the devices identified by the codes “Sblast” and “Windows Sound”. Compatible devices are identified by identification codes having names that are dissimilar to the identification code for the primary device.

For the preferred embodiment, the selection of a device driver corresponding to a compatible device is determined by the following convention: if a primary device driver is not available to support the particular device, then the device driver for the compatible device having the highest priority ranking is selected from the compatible device driver candidates. The identification code for the compatible device having the highest priority ranking is preferably listed within the compatible device identification field prior to any of the remaining identification codes. Thus, the identification codes for compatible devices are ordered based upon priority ranking assigned to those devices. Assuming the absence of the identification code for that primary device in the compatible device information field, this convention indicates that the “Sblast” device driver should be selected to support the “Audio B3” device based upon the order of the identification codes for the listed devices.

FIG. 5 is a flow chart diagram that illustrates the preferred steps for a method of obtaining a device driver for use with a device of the computer. Turning now to FIGS. 1 and 5, a computer-implemented process for obtaining a device driver is started in step 100 and proceeds to step 102, where a determination is made whether the records of the computer database 16 contain an entry designating that a primary device driver corresponding to the particular device 20 is available on the computer 8. To locate the record associated with the particular device 20, the computer database 16 is searched by using the identification code for the particular device 20 as the entry key. If the identification code for the particular device 20 is found in both the device identification and compatible device identification fields of a selected record, then the “YES” path is followed to step 104. This affirmative response indicates that the primary device driver for the particular device 20 can be obtained on the computer 8. A device driver maintained by the computer 8 typically can be retrieved by accessing a corresponding file on the fixed disk of the computer 8 and reading the stored device driver. For the preferred operating system 10, certain device-related information, including the identity of device drivers for the corresponding device, is stored within information files called INF files. In the step 104, the device driver corresponding to the primary device is selected and assigned for use by the particular device 20. The process concludes if the primary device driver is available. In contrast, if a positive match is not achieved, then the “NO” path is followed to the step 106.

If the primary device driver for the device 20 is not available, then the compatible device identification field for the selected record is preferably searched in step 106 for an identification code that corresponds to a device that is “compatible” with the particular device 20. If one or more of the identification codes representing compatible devices are contained in this field, then the “YES” branch is followed to the step 108. In step 108, the compatible device identification field is also searched for the identified compatible device having the highest priority ranking. The preferred compatible device is listed first within the compatible device identification field. Upon finding the preferred compatible device, the process proceeds to the step 110. In the step 110, the device driver corresponding to the compatible device having the highest priority ranking is selected and assigned for use with the particular device 20, thereby concluding the search for a compatible device driver.

If the response to the step 106 is negative, then the “NO” branch is followed to the step 112. The user is requested in step 112 to supply a substitute device driver for the supporting operation of the device with the computer 8. This request is typically supplied as a text-based statement displayed on a display or monitor for the computer 8 or as an audio prompt generated by the computer 8. In response to the request, the user can insert within the appropriate computer drive a flexible disk or another form of appropriate electronic media containing the device driver program, thereby permitting the computer 8 to access the device driver program. In response to reading the disk, in step 114, the computer 8 stores the device driver program on a selected mass storage memory device.

In step 116, the substitute device driver is obtained and instructed to enable the particular device 20 for operation with the computer 8. In addition, to maintain the records on the computer database 16, the identification code for the device associated with the new substitute device driver is listed in the appropriate record(s) of the computer database 16. This database update is achieved by adding the identification code for the device driver within the compatible device identification field for the record associated with the particular device 20. In this manner, the archival record indicates that the substitute device driver supports the operations of the particular device 20 and has been installed for use on the computer 8.

Automated Configuration System Components

FIG. 6 is a block diagram that illustrates the components and their structural communications links for the preferred embodiment of the operating system 10. Referring to FIGS. 1 and 6, the operating system 10 comprises numerous software programs or modules, including enumerators 150, a hardware tree 152, a registry 153, arbitrators 154, device drivers 156, a configuration manager 158, and a device configuration database 160. The enumerators 150, the registry 153, the arbitrators 154, and the device drivers 156 are associated with the configuration manager 158. It will be understood that the operating system 10 also preferably interacts with a modified BIOS program of the computer control system 21 and various hardware components of the computer 8, including the system busses 18 and the devices 20, to support the configuration system.

These components are generally described within sections headed by their respective identifying legends and are best shown in FIGS. 6-8. A more detailed review of certain components, namely the enumerator 150 and the arbitrator 154, is also supplied below with respect to FIGS. 9-13.

Enumerators

The enumerators 150 operate to report the identities of detected devices 20 on the system busses 18 in response to certain events that affect the operating state of the computer 8. These events include changes to the state of power supplied to the computer 8, including the states Power-on, Standby, Suspend, or Resume. The events also include the insertion of a device onto or the removal of a device from a system bus, or the insertion into or the removal of a computer from a docking station or an expansion chassis. It will be appreciated that this connection (or removal) of a device 20 to the computer 8 can be completed by a physical connection or as a logical connection via a wireless communication link or a network. In addition, for certain devices 20, the enumerators 150 also can transmit assigned resource elements from the configuration manager 158 for use by the devices 20 in response to an allocation of the resources 14.

Each enumerator 150 is assigned to a component of the computer 8 that is capable of having children, namely, those components that provide a connection for yet another hardware component. It will be understood that computer busses, such as the system busses 18, represent a common mechanism for connecting adapter boards and peripheral devices to a personal computer. In similar fashion, for the preferred computer control system 21, the modified BIOS program represents a mechanism for providing a central connection for the system-level devices of a personal computer, including the interfaces for the keyboard controller, the display controller, the I/O controller, and the serial and parallel controllers. Thus, for a typical personal computer, the enumerators 150 can be assigned to the computer busses and to the modified BIOS program that supports the configuration of boot-level devices. For the computer 8 shown in FIG. 1, individual enumerators 150 are assigned to the system busses 18, including the local bus, the ISA bus, SCSI bus, and the PCMCIA bus, and to the modified BIOS program of the computer control system 21.

For each system bus 18, the associated enumerator 150 is programmed to recognize the operating characteristics of its assigned computer bus and to support the configuration of the devices 20 connected to that computer bus. Specifically, these enumerators obtain device-related information from the devices 20 and subsequently store such information within a central memory location of the hardware tree 152. As outlined above, this collection of device information is initiated in response to the events affecting the enumerator's assigned system bus 18, such as the insertion or removal of a device or a change in the power state of the computer 8. It will be understood that this collection of device information from the devices 20 in the computer 8 is described as an enumeration process.

Likewise, for the computer control program 21, an enumerator 150 can be programmed to recognize the system-level devices of the computer 8 and to support the configuration of those system-level devices. The enumerator 150 assigned to the modified BIOS program accesses the default-type configuration parameters for the system-level devices from the modified BIOS in response to events affecting the computer's operating state, including the power-on event, and stores this information within the hardware tree 152. Furthermore, the enumerator 150 for the modified BIOS program can be programmed to detect the insertion of the computer into or the removal of the computer from a docking station and outputs an indication of these events to the configuration manager 158.

A unique system bus code is associated with each of the enumerators 150. For example, the ISA bus enumerator has a particular system bus code that is different from the system bus code assigned to the MCA bus enumerator. An enumerator 150 forms a device identification code for each device 20 connected to the assigned system bus 18 by appending its system bus code to the identification code for the device 20. The device identification code also can include an instance number that is assigned by the enumerator 150 to distinguish identical devices 20 connected to the same system bus 18.

An instance number can be obtained by the enumerator 150 from the device 20 itself, if available, or is assigned to the device 20. By way of example, for the ISA bus, the ISA bus enumerator assigns an instance number to a logical device based upon a serial number that is stored in the memory storage device 29 associated with that device. If no serial number is available for the device 20, then the enumerator 150 is required to use some other unique attribute to generate an uniquely addressable instance number. For the PCMCIA bus, an alternative scheme for assigning an instance number is based upon the use of the slot number for the bus socket connected to the device 20.

The enumerator 150 also obtains logical configuration data for each of the devices 20 of the computer 8. Logical configuration data is preferably linked to corresponding device information to maintain a logical link with the represented device 20. For a typical device, the device identification code and the logical configuration data, which are collectively referred to as device information, are preferably stored within a device node associated with that device. Each device node is preferably maintained in the tree-like memory structure of the hardware tree 152, as described below.

As a result of the resource assignment process, the enumerators 150 receive data packets containing assigned resource elements for the devices 20. In response to receiving an assignment of the resources 14 for a particular device, the enumerator 150 accesses the appropriate device node to store the resource assignment. In this manner, the assigned resource information is maintained in a central memory location that is accessible by the device and, as required, by the device driver corresponding to that device. Thus, it will be appreciated that the assigned resources for the each of the devices 20 are stored within corresponding device nodes.

The enumerators 150 provide an abstraction layer that effectively separates the controller portion of the operating system 10, the configuration manager 158, from the underlying bus structures of the computer 8. By placing the system bus-level information within the inventive concept of the driver-like enumerators 150, the operating system 10 can be adapted to operate with a variety of present and future computer bus architectures. Thus, unlike conventional operating systems, the configuration manager 158 can communicate with a variety of system busses without any knowledge of the characteristics of those system busses because such information is supplied by the abstraction layer of the enumerators 150. The structure and operations of the enumerators 150 are described in more detail below with respect to FIGS. 9 through 11.

Hardware Tree

The hardware tree 152 supplies a hierarchical representation of the device identities, the resource usage requirements, and the resource assignments for the present devices 20 operating with the computer 8. The data structure for the hardware tree 152 is maintained in a hierarchical arrangement of device nodes within an allocated portion of the nonvolatile memory supplied by the computer memory 22. This stored information can be accessed by the operating system 10, specifically the configuration manager 158, by device drivers, or by application programs (via a common interrupt).

Each device node in the hardware tree 152 represents one of the devices 20 presently installed for operation with the computer 8 and generally contains three main attributes that describe the capabilities and resource requirements for that device. Upon the completion of data storage, the device node will include the device identification code, the logical configuration data, and the assigned resource elements. The device identification code is useful for accessing the hardware tree 152 and maps into a unique entry key for the archival data structure of the registry 153. It will be appreciated that the device information for each device 20 is stored within a corresponding device node to enable all information pertaining to a common device to be maintained in a central storage location with the hardware tree 152.

The device information collected from the devices 20 by the enumerators 150 is used to populate the device nodes of the hardware tree 152. However, it will be understood that certain existing interface boards or peripheral devices do not include a mechanism for storing configuration data. Upon identifying these “legacy” devices, at least a part of the hardware tree 152 can be populated when the configuration manager 158 copies information for those devices to the hardware tree 152 from an available information source, such as the device configuration database 160 or text-based information files stored on a mass memory storage device of the computer 8.

Because the hardware tree 152 reflects the identities, resource requirements, and current resource allocations for the existing devices 20, the data stored within the hardware tree 152 can change each time the computer 8 boots with a new hardware configuration or in response either to adding a new device or to removing an existing device. Likewise. the insertion into or withdrawal of the computer 8 from a docking station can modify the data stored by the hardware tree 152. Accordingly, it will be appreciated that the hardware tree 152 is a computer database containing device information which reflects a snapshot of the characteristics for the devices presently installed for operation with the computer 8.

A user can access the device configuration information in the hardware tree 152 to verify the present configuration of its computer. Access to this useful information can be achieved by either local or remote communications means, such as directly from the computer itself or via a network.

Referring to FIG. 7A, which illustrates the tree-like data structure of the hardware tree 152 for the computer 8 shown in FIG. 1, the hardware tree 152 contains a set of device nodes, including a device node 162 for the local bus, a device node 164 for the ISA bus, a device node 166 for the network card, a device node 168 for the modem card, a device node 170 for the SCSI bus, and a device node 171 for the PCMCIA bus.

A branch between any pair of the device nodes of the hardware tree 152 indicates that the connected device nodes share a common link. For example, upon entering the hardware tree 152. the device node 164 for the ISA bus can be reached only by first passing through the local bus device node 162 and a branch 172. This defines an interconnection between those system busses 18 (FIG. 1), thereby supplying an indication that the ISA bus is connected to the local bus. Likewise, both the network card and the modem card are connected to the ISA bus because branches 174 and 176 respectively extend from the device node 164 to the device nodes 166 and 168. In similar fashion, a branch 178 extending between the device nodes 164 and 171 indicates that the PCMCLA bus is connected to the ISA bus, and a branch 179 extending between the device nodes 162 and 170 indicates that the SCSI bus is connected to the local bus.

FIG. 7B illustrates the data structure for a representative device node of the hardware tree 152, in this case, the device node 168 for the modem card. Referring to FIGS. 7A and 7B, upon completion of the configuration of the modem card, the device node 168 preferably includes the device identification code, logical configuration data, and assigned resource elements. For the modem card, the device identification code is “*PNP0A00\Modem1234\0”. A review of this device identification code indicates that the modem card is connected to the ISA bus, which is represented by the system bus code “*PNP0A00”. In addition, the modem card is assigned an identification code “Modem1234\0” and is the first identified modem card of its type on the ISA base as evidenced by the instance number “0”. The logical configuration data includes a specified combination of resource elements required for operation of the modem, in this case, the interrupt IRQ3 and the I/O port I/O3F8. This is followed by the assigned resource elements, which, for this example, include this same resource combination of the interrupt IRQ3 and the I/O port I/O3F8.

It will be appreciated that the above description of the attributes for the device node 168 is supplied as a representative example of the information that can be stored within a device node of the hardware tree 152. However, it will be understood that the data stored within the device nodes of the hardware tree 152 can be different because each device node contains data describing the identification and resource requirements for the represented device.

Registry

Returning now to FIG. 6, the registry 153 is a hierarchical, tree-structured database for storing various software and hardware parameters, including device information. The registry 153 is initially stored within the nonvolatile memory of the computer database 16 upon installing the operating system 10 for use on the computer 8. The registry 153 preferably contains hardware archival data, which is a superset of the memory-resident hardware tree 152, and software archival data containing software-related parameters and software driver information.

In contrast to the hardware tree 152, which contains device information for currently detected devices 20, the registry 153 contains a complete listing of any and all hardware components that have been installed on the computer 8. In this manner, even if a particular device 20 is removed for one session and then available again for the next session, the user will not be required to set-up the device again for the next session because all necessary device information is contained in the registry 153. Thus, if a particular device is removed from the computer 8, the device information for that device 20 remains in archival storage within the registry 153.

FIG. 8 shows the tree-like data structure for the registry 153. Referring to FIGS. 6 and 8, a root key 180 includes two branches, the software archive 182, which contains software archival data, and the hardware archive 184 containing hardware archival data The software archive 182 contains information related to location and identity of various program files, including the device drivers 156. The hardware archive 184 can contain hardware-related information, including the identity of detected devices; any user-defined configuration; the “last working configuration”; and information concerning the loading of device drivers. The information maintained by the software archive 182 and the hardware archive 184 is organized into logical classes and additional branches extending from the archive branches are associated with the classes or categories of this information.

Focusing on the hardware archive 184 in FIG. 8, an ENUM branch 186, which represents the enumerators 150 for the operating system 10, extends from the hardware archive 184. The ENUM branch 186 includes the enumerator branches 188, 190, 192, and 194, which define the respective enumerators 150 for the local bus (root), the modified BIOS program (SysBIOS), the ISA bus (ISAENM), and the SCSI bus (SCSIENM). It will be understood that the device identification codes, which are assigned by each enumerator 150 to the detected devices 20, operate as a key to the corresponding entries in the hardware archive 184 of the registry 153.

The registry 153 also contains device branches for each of the devices 20 that have been installed during both past and present operations of the computer 8. These tree-like device branches, which can extend from each of the enumerator branches, such as the branches 188, 190, 192, and 194, represent the past and present devices of the computer 8. The device branches preferably contain pertinent device-related data, including an identification code, logical configuration data, and a pointer to the device driver for that device. Accordingly, the device branches, such as the branches 196 and 198, represent the archival device-related information for devices that have operated in the past or at present with the computer 8 and can extend from each of the enumerator branches 188, 190, 192, 194.

The root branch 188, which extends from the ENUM branch 186, can include device branches representing device-related information for existing devices 20 that lack a mechanism for storing the identification code and the resource usage data. These devices, which are typically referred to as legacy or static devices, can be represented by branches extending from the root branch 188. In similar fashion, the SysBIOS branch 190, otherwise referred to as the system BIOS branch, also extends from the ENUM branch 186 and can include device branches representing the system-level devices located on the motherboard of the computer 8. In addition, the SCSI branch 194, which extends from the ENUM branch 186, can include device branches representing device-related information for SCSI bus-compatible devices. Although it will be recognized that a personal computer is operable with system-level devices and one or more legacy devices and/or SCSI-compatible devices, device branches for these types of the devices 20 are not shown in FIG. 8 to simplify the illustration of the registry 153.

Device branches 196 and 198, which extend from the ISAENM branch 192, are examples of typical device branches and represent the devices 20 that have been or are at present connected to the ISA bus. It will be appreciated that the device branches 196 and 198 represent typical devices connected to the ISA bus in the computer 8 and are shown in FIG. 8 as examples of the device branch concept for the registry 153.

The Modem1234\0 branch 196, which extends from the ISA bus branch 192, indicates that a single device, in this case, the modem card having the identification code “Modem1234\0”, is (or has been) connected to one of the system busses 18 (FIG. 1), namely the ISA bus. In general, the identification code can represent the manufacturer's identity, the model of the corresponding device, and the instance number. For this example, the manufacturer is “Modem”, the model is “1234”, and the instance number is “0”.

The PCMCIAENM branch 198 extending from the ISA bus branch 192 indicates that another device 20 having the device identification code PCMCIAENM is (or has been) connected to the ISA bus. This device identification code indicates that the detected device 20 is actually another bus, specifically the PCMCIA bus, which is capable of supporting the connections of additional devices 20. Thus, the branch 198 also represents an enumerator branch because an enumerator 150 is assigned for the enumeration of any of the devices 20 connected to the PCMCIA bus. If the PCMCIA bus represented by this device branch is the parent for “children” devices, then the PCMCIAENM branch 198 can include device branches representing such devices on the PCMCIA bus.

Arbitrators

Returning again to FIGS. 1 and 6 it will be seen that each of the arbitrators 154 is assigned to a particular resource 14. Arbitrators 154 operate to determine the assignments for their respective resources 14 in view of the resource requirements and dependencies for the devices 20 connected to the computer 8. The arbitrators 154 are programmed to recognize the characteristics of their assigned resources 14, including the specific elements of the corresponding resources. For example, the arbitrator 154 for the 10 ports 28 has a built-in knowledge base which confirms that a conflict can occur when assigning 16-bit addresses if the computer 8 is configured with one or more devices 20 that are performing 10-bit decoding operations. In addition, the arbitrators 154 preferably maintain a table of resented resource elements to insure compatibility with the fixed designs of existing computer components. Reserved resource elements are generally available for use by certain devices 20 that are known to require the use of such resource elements.

In response to a potential working configuration for the detected devices 20, each arbitrator 154 operates to allocate its respective resource elements to the various devices 20 that require use of such resources during computer operations. For the computer 8, the arbitrators 154 are assigned to handle access to the message addresses for the memory 22, the interrupts 24, the DMA channels 26, and the I/O ports 28. The arbitrators 154 are implemented as individual components that are separate from the remaining portion of the operating system 10 to allow the extension of the preferred operating system to other possible resources of a personal computer.

The arbitrators 154 work in tandem with the configuration manager 158 to complete the allocation and assignment of resources 14 to the devices 20. For a selected arbitrator 154, the configuration manager 158 supplies one or more possible configurations of elements of the corresponding resource 14. This possible configuration is based upon the device information acquired for all of the devices 20 of the computer 8. It will be appreciated that the resource portion of this device information, which can specify resource ranges, particular resource elements and resource dependencies for the devices, will support the prioritized ranking of possible configurations by the configuration manager 158.

For a selected resource 14, if a working configuration solution is developed by the corresponding arbitrator 154, then the resulting resource element assignments are supplied to the configuration manager 158 to enable the allocation of the assigned resource elements to the proper devices 20. However, if a potential resource conflict for a resource element is located by the arbitrator 154, then an error flag is set to advise the configuration manager 158 that a working configuration is not available for this possible configuration. In this event, the configuration manager 158 can either supply an alternative configuration to this arbitrator 154, if available based upon the device information, or can supply a message to the user that requests user input to resolve a resource conflict. Thus, it will be appreciated that the arbitrators 154 develop resource assignments for their respective resources 14 in an iterative fashion based upon the collected device information.

The structure of and the operations conducted by the arbitrators 154 will be described in more detail below with respect to FIGS. 12 and 13.

Device Drivers

Device drivers 156 support communications between the devices 20 and the computer 8. For proper computer operations, each device 20 is represented by a corresponding device driver 156. Information for the device drivers 156 is stored within the registry 153 or can be accessed by reading certain configuration files of the preferred operating system 10, such as the text-based information files called .INF files.

Configuration Manager

The configuration manager 158 controls the various configuration tasks conducted by the enumerators 150, the hardware tree 152, the registry 153, the arbitrators 154, and the device drivers 156. When the computer 8 boots, the configuration manager 158 instructs the enumerators 150 to identify the devices 20 of the computer 8, thereby enabling the acquisition of device information for those devices. The configuration manager 158 subsequently examines the device nodes of the hardware tree 152 and, for the devices 20 that are newly installed, will direct the transfer of device information to the registry 153 for archival storage.

The configuration manager 158 also controls the acquisition of appropriate device drivers 156 in response to the stored device information and directs the allocation of the resources 14 in response to the resource assignments supplied by the arbitrators 154. Assigned resources are distributed by the configuration manager 158 to the appropriate enumerators 150 to support the resource allocation operation. To complete the configuration process, the configuration manager then controls the loading of the device drivers 156. Accordingly, it will be appreciated that the configuration manager 158 effectively controls the configuration operations by operating as a “traffic cop” to direct the operations conducted by the other components of the operating system 10.

Device Configuration Database

The device configuration database 160, which is typically implemented as a program file of the operating system 10, contains information about known computer components, including certain devices 20, and their configuration requirements. Upon loading the operating system on the computer 8, this program file is preferably stored on a computer mass storage memory device.

Unlike the registry 153, the information stored in the device configuration database 160 does not necessarily represent data about the set of devices 20 that have been connected at one time or another for operation with the computer 8. Instead, the device configuration database stores general component-level information about existing devices that can be installed for operation with a conventional personal computer, such as the computer 8.

The configuration manager 158 can access the device configuration database 160 for each newly installed device represented in the hardware tree 152 and, if available, copies relevant information concerning the identified device into the registry 153. The relevant information, which typically includes compatible device information and known resource requirements and dependencies, is maintained in the registry 153 by linking this information to the identification code for the identified device 20. Thus, it will be understood that the identification code operates as an entry key for the device configuration database 160.

In addition, during the initial set-up of the operating system 10, information is preferably obtained from the device configuration database 160 for known “legacy” computer components that can be installed for operation with a conventional personal computer. Thus, this device information is preferably stored in the device configuration database 160 and, during the initial set-up of the operating system 10, transferred to the registry 153 under the root branch 188, as illustrated in FIG. 8.

Referring now to FIGS. 1, 6 and 7, the configuration tasks are preferably conducted in at least two phases, a first configuration phase occurring after the computer 8 boots, and a second configuration phase conducted at the time of device initialization. During the first configuration phase, the modified BIOS program of the computer control system 21 initiates the enumeration of the devices 20 that are system-level devices on the motherboard of the computer 8. Although a device node will be formed and stored within the hardware tree 152 for each of the system-level devices, most of these device nodes are not shown in FIG. 7 to simplify this explanation of the configuration phases. Thus, for purpose of this discussion, only the computer local bus 13 (root bus) and the integrated bus 15, specifically the ISA bus, are considered as being identified by the operation conducted by the enumerator 150 for the modified BIOS program.

As shown in FIG. 7, the device identification codes for the local bus and the ISA bus are respectively “Root\Root” and “Root\*PNP0A00\0”. Focusing specifically on the device node 164 for the ISA bus, the system bus code is “Root” and the identification code is “*PNP0A00\0”.

After enumerating the system-level devices and detecting the integrated bus 15, device-related information is stored in the hardware tree 152 for the existing legacy devices that were designed for use with conventional personal computers. The legacy devices are preferably added to the hardware tree 152 under the local bus device node 162. Thus, the device node 170 for the SCSI bus is added at this time to the hardware tree 152 because the SCSI bus is considered to be an existing legacy-type device. For the device node 170, the system bus code is “Root” and the identification code is “EISAID,” which in combination form the device identification code “Root\EISAD\0.” At the conclusion of the first configuration phase, the hardware tree 152 contains the device nodes 162, 164 and 170, and the registry 153 has been updated as necessary to reflect any new device information contained in the hardware tree 152.

For the second configuration phase, the configuration manager 158 examines the hardware tree 152 for the entries associated with each device node of the hardware tree 152 and determines the set of devices 20 previously identified by the first configuration phase. In view of the entries for the system busses 18, specifically the ISA bus and the SCSI bus, the configuration manager 158 instructs the assigned enumerators 150 to conduct enumeration operations for the ISA bus and the SCSI bus. For the ISA enumerator, device information is acquired for each of the devices 20 directly connected to the ISA bus, specifically the adapter boards implemented by network card and the modem card, and a system bus 18, the PCMCIA bus. Thus, three new device nodes, the device nodes 166 (network card), 168 (modem card), and 171 (PCMCIA bus) are now added to the hardware tree 152 under the respective device identification codes “*PNP0A00\Net\0”, “*PNP0A00Modem\0”, and “*PNP0A00\PCMCIA\0”.

In response to the identification of the additional devices 20, the entries in the registry 153 also are updated to reflect the detection of newly installed devices as required. In turn, the appropriate device drivers 156 are identified for the network card and the modem card. The configuration manager 158 then instructs the appropriate arbitrators 154 to develop an assignment for the resources 14 based on the resource requirements and constraints for the detected devices 20. In particular, the configuration manager 158 calls a selected arbitrator 154 and, if it returns a valid resource allocation, then the configuration manager 158 will call the next arbitrator 154 until all resources are properly allocated. If an invalid allocation is returned by one of the arbitrators 154, the configuration manager 158 initiates a new round of exchanges with the arbitrators 154 based on other possible configurations supported by the various devices 20. The assigned elements of the resources 14 will be supplied by the configuration manager 158 to the detected devices 20 via the abstraction layer supplied by the enumerators 150.

Upon a determination of a proper working configuration and assignment of the necessary resources, the configuration manager 158 will instruct an associated device driver loader program (not shown) to load the identified device drivers 156. The identified device drivers 156 are then loaded to enable the operation of the network card and the modem card with the computer 8.

In view of the foregoing, it will be understood that a similar configuration process would be completed for the devices 20 connected to the PCMCIA bus and the SCSI bus of the computer 8.

The operations implemented by the computer 8 are supported by the modules of the operating system 10, including the enumerators 150, the hardware tree 152, the registry 153, the arbitrators 154, the device drivers 156, the configuration manager 158, and the device configuration database 160, and the computer control system 21. Specifically, the operating system 10 comprises a plurality of computer software programs and at least one program is associated with each of the components 150. 152, 153, 154, 156, 158, and 160. Those persons skilled in the art will understand that the described computer-implemented processes can be coded as computer software programs using known software development techniques.

Enumerators

In view of the foregoing, it will be useful to revisit the subject of the enumerators 150 and to review the structure of and the tasks conducted by the enumerators 150, as described below with respect to FIGS. 9-11. Those skilled in the art will appreciate that each standard bus architecture typically requires a unique process for configuring connected devices based upon the characteristics for the system bus. Accordingly, each enumerator 150 is assigned to a corresponding system bus 18 (or the modified BIOS program of the computer control system 21) and operates to support device configuration tasks in view of the characteristics of its assigned component. Although the operations of the enumerator 150 have been described in general terms, the actual implementation of those operations by each enumerator 150 is specific to the architecture for its assigned component. Thus, the enumerators 150 facilitate the development of an operating system that is independent of the characteristics of computer bus architectures because the enumerators 150 support the bus-specific tasks for device configuration.

Enumerator Elements

As required by the characteristics of its assigned system bus 18, each enumerator 150 can conduct up to three separate tasks, specifically enumeration, device configuration, and detection of dynamic events affecting the operating state for the computer 8. To facilitate a review of the operations by the enumerators 150, these functions are shown in FIG. 9 as separate elements, specifically an enumerate element 200, a configure element 202, and an event detect element 204. Referring to FIGS. 1, 6, and 9, the enumerator 150 communicates with its assigned component, such as the system bus 18, and the configuration manager 158 during the operations conducted by the elements 200, 202, and 204. In addition, the enumerator 150 communicates with the hardware tree 152, which is stored in the computer memory 22, to store device information and assigned resource data. As shown in FIG. 9, the enumerator 150 is assigned to one of the system busses 18.

In response to an enumerate instruction from the configuration manager 158, the enumerate element 200 begins to enumerate each of the devices 20 directly connected to its system bus 18. A detection module 206 detects a selected device on the system bus 18. For example, for the ISA bus enumerator, the detection module 206 instructs each device 20 to enter an inactive state and thereafter isolates a particular device 20 from the remaining devices on the system bus 18. A collection module 208 can thereafter obtain the device information from the detected device. In this manner, the detection module 206 and the collection module 208 operate in tandem to enable the enumerate element 200 to collect device information from each of the devices 20 on its assigned system bus.

The collection module 208 can include submodules 210, 212, and 214 to support the acquisition of device information from the devices 20. Specifically, the submodule 210 supports the retrieval of the identification code for the device 20 and the submodule 212 appends to the retrieved identification code the bus code for the assigned system bus 18, thereby forming the device identification code for that device. The submodule 214 supports the retrieval of logical configuration data to complete the acquisition of device information from the particular device 20. An additional submodule (not shown) can support the storage of the device identification code and the logical configuration data within a common device node of the hardware tree 152.

The configure element 202 responds to a data packet containing assigned resources by storing the assigned resource information within the appropriate device nodes of the hardware tree 152. The configure element 202 includes modules 218, 220, and 222 to support this communication of assigned resources between the configuration manager 158, the hardware tree 152, and, as required, the devices 20. Specifically, the module 218 receives the data packet of assigned resources 14 from the configuration manager 158. In response, the module 218 supplies the data packet containing the assigned resources to the modules 220 and 222. The module 222 can supply the assigned resources to the appropriate devices 20 whereas, in contrast, the module 220 stores the assigned resources within the appropriate device nodes of the hardware tree 152.

The event detect element 204 is responsive to the detection of a dynamic event that causes a change in the operating state of the assigned system bus 18. As described in more detail with respect to FIGS. 11A and B, the dynamic events can include connecting another device 20 to the assigned system bus 18 or removing one of the detected devices 20 from the system bus 18. The connection or removal of a device for certain system busses, such as the ISA bus and the PCMCIA bus, is represented by an interrupt signal supplied to the event detect element 204. In contrast, the event of powering the computer 8 is represented by a command signal issued by the configuration manager 158 to the event detect element 204. Accordingly, the event detection operation by the event detect element 204 represents the reception of the interrupt signal or the command signal and the resulting detection signal output in response to the reception of these signals. In response to a detection signal output by the event detect element 204, the configuration manager 158 typically initiates enumeration operations by outputting the enumeration instruction to the enumeration element 200.

The event detect element 204 also responds to commands contained in certain instruction signals from the configuration manager 158. These commands typically instruct the event detect element 204 to conduct specified query-type operations, including deletion of device information stored within a particular device node and to start or to terminate designated tasks.

Identification of Devices Connected to a System Bus

FIG. 10 is a flow chart diagram illustrating the preferred steps for the enumeration process that identifies the devices on a system bus of a computer. Referring to FIGS. 6 and 10, the enumeration process starts at step 250 in response to an event that effects an asynchronous change in the operating state of the computer 8. Specifically, the enumeration process starts in response to powering the computer 8, adding a new device 20 to the computer 8, removing an existing device 20 from the computer 8 or, inserting the computer 8 into or removing the computer 8 from a docking station or expansion unit. In response to any of these events, the enumeration process starts at step 250 and proceeds to step 252 for the selection of a system bus 18. In step 256, a particular device 20 is then detected on the selected system bus 18 to enable the collection of device information.

To acquire the device information, in step 258 an identification code is retrieved from the particular device 20. In step 260, the system bus code, which is associated with the enumerator 150 assigned to the selected system bus 18, is appended to the retrieved identification code. This combination of the identification code and the system bus code forms the device identification code.

In similar fashion, the logical configuration data is retrieved from the particular device 20 during the step 262. Both resource requirement information and resource dependency information are accessed in the step 262. This completes the collection of device information from the particular device 20. To associate or link the logical configuration data with the particular device 20, the logical configuration data is added to the device identification code in the step 264. This completes the process of collecting device information for the particular device 20.

To acquire device information from the remaining devices 20, it is necessary for the enumeration process to continue. In step 266, an inquiry is conducted to determine if device information has been collected from the remaining devices 20 on the selected bus 18. If the response to this inquiry is negative, then the “NO” branch is followed to the step 256 and the collection process continues. However, if the answer is positive, then the “YES” branch is followed to the step 268 and the enumeration process for the selected system bus 18 is concluded.

For the selected system bus 18, it will be understood that the enumerator 150 assigned to this bus operates to detect each of the directly connected devices 20 and stores the collected device information within device nodes in the hardware tree 152. The enumerators 150 assigned to the remaining system busses 18 conduct similar data collection operations to complete the data entries in the hardware tree 152. In this manner, device nodes for the detected devices are constructed and stored in the hardware tree 152. As a result of this enumeration process, each device node in the hardware tree 152 contains at least (1) the combination of the system bus code and the identification code and (2) the logical configuration data for the corresponding devices.

During the enumeration process, certain information, including the device identification code and the logical configuration data, are obtained for the devices 20 of the computer 8. As previously described, the device :identification code includes an identification code that uniquely identifies the associated device 20 and the logical configuration data preferably includes both resource requirement and resource dependency information. For example, for ISA-compatible devices, the identification code, also described as a serial identifier, is retrieved from the device by reading the serial data in a bit-wise manner. It will be useful to review the representative device-related information for devices compatible with the widely used ISA bus architecture. Nevertheless, it will be appreciated that the data structures for the identification code and logical configuration data associated with devices compatible with other bus architectures can be different from the data structures for ISA-compatible devices. Accordingly, the data structures for the device-related information may be defined by the corresponding bus architecture. In view of the foregoing, Table 2 shows the preferred data structure for an identification code of an ISA-compatible device.

TABLE 2 Field Name Length Definition Vendor ID Byte 0 8 bits Bit[7] - 0 Bits[6:2] - First character in compressed ASCII Bits[1:0] - Second character in compressed ASCII bits[4:3] Vendor ID Byte 1 8 bits Bits[7:5] - Second character in compressed ASCII bits[2:0] Bits[4:0] - Third character in compressed ASCII Vendor ID Byte 2 8 bits Product Number (Vendor Assigned) Vendor ID Byte 3 8 bits Product Number (Vendor Assigned) Serial/Unique Number 8 bits Unique device number so the system Byte 0 can differentiate between multiple cards of the same type in one system. Bits[07:00] Serial Number Byte 1 8 bits Serial Number Bits[15:08] Serial Number Byte 2 8 bits Serial Number Bits[23:16] Serial Number Byte 3 8 bits Serial Number Bits[31:24] Checksum 8 bits Checksum of ID and serial number verifies that the information has been correcty read from the device.

Referring to Table 2 and FIG. 1, the data structure for the identification code preferably includes three separate data fields for data representing a vendor identification number, also described as a Vendor ID, a serial number, and a checksum.

The Vendor ID comprises two 8-bit bytes containing a three character compressed ASCII identification of the vendor or manufacturer and two 8-bit bytes for a manufacturer-specific device code. The first portion of the Vendor ID identifies the vendor or manufacturer for the peripheral device or adapter board. The second portion of the Vendor ID is used by the vendor or manufacturer to identify the particular type of device. For example, the manufacturer may develop and market a variety of peripheral devices and adapter boards. Thus, the second portion allows the manufacturer to distinguish a first device type from a second device type. Similarly, if the peripheral device or adapter board contains more than one of the devices 20, such as a parallel interface and a serial port interface, then the manufacture can use the second portion of the Vendor ID to indicate that the particular model of board contains two separate interfaces or devices. It will be appreciated that the Vendor ID serves as a unique identifier for the associated device.

The serial/unique number is a 32-bit serial number which is useful for differentiating between multiple devices 20 having the same Vendor ID when such devices are connected to the same bus system 18. For this reason, the serial number is preferably used as an instance number during the enumeration process for the ISA-compatible components. Similar to the Vendor ID field, the serial number field comprises four 8-bit length bytes. Collectively, the Vendor ID and the serial number fields supply 64 bits to permit the unique identification of the manufacturer, the board or device type, and the serial number.

The checksum field is used to insure that no conflicts have occurred while reading the identification code from the board containing the device(s) 20. A checksum verification operation is conducted when the serial data is acquired from the device 20 by the computer 8. The use of a checksum is a conventional technique for detecting data transfer errors and will not be described in detail herein.

Continuing with the representative example of the ISA-compatible device, logistical configuration data is retrieved from this device one byte at a time in a sequential fashion. The logical configuration data is preferably read in serial fashion from the device 20 almost immediately after reading the checksum field of the identification code. The data structures for the logical configuration data support both small and large information items to minimize the amount of storage needed on the ISA compatible component. The small and large information items are distinguished by “tagged” data structures. Tables 3A-B show the preferred data structure and the information for the small information items of an ISA-compatible device.

TABLE 3A Field Offset Tag Bit [7] Tag Bits [6:3} Tag Bits [2:0] Byte 0 Type = 0 Small item name Length = n bytes Bytes 1 to n Actual information

TABLE 3B Small Item Name Value Version number 0×1 Logical device ID 0×2 Compatible device ID 0×3 IRQ format 0×4 DMA format 0×5 Start dependent function 0×6 End dependent function 0×7 I/O port descriptor 0×8 Fixed location I/O port descriptor 0×9 Reserved 0×A-0×D Vendor defined 0×E End tag 0×F

Referring to Table 3A, the data structure for the small item data has a size of 2-8 bytes. The first byte defines the type and size for most information and is followed by one or more bytes of actual information. Bit 7 of the first byte is used as the tag identifier to differentiate between a small item or a large item data type. Bits 3-6 define the small item name and bits 0-2 define the variable length of the small item data as “n” bytes. The remaining bytes within the small data type structure define the small data items for the logical configuration data.

Referring now to Table 3B and FIG. 1, the small information items are defined for the ISA-compatible devices. Specifically, the small 15 information items can include a version number, a logical device ID, a compatible device ID, an IRQ format, a DMA format, a start dependent function, an end dependent function, a I/O port descriptor, a fixed location I/O port descriptor, a vendor-defined field, and an end tag. These data items describe the resource configuration information for the associated peripheral device or adapter board.

The version number identifies the version of the configuration specification with which the associated board or device is compatible. The version number includes a vendor-specific version number and information about optional commands supported by the device.

The logical device ID field comprises a 32-bit identifier for the associated device 20. It will be understood that certain interface boards or peripheral devices may contain more than one function, such as controlling both video and disk functions. Thus, each function is identified as a logical device 20 that is associated with separate logical configuration data. This identifier also supports the selection of a device driver for the device 20. The field also includes a bit that can be set if the device 20 should be activated by the computer control system 21 when the computer 8 is booted.

The compatible device ID field provides the identification codes of other devices with which the associated device 20 is compatible. As previously described with respect to FIG. 4, the operating system 10 uses the compatible device ID code to support the loading of a compatible device driver if the primary device driver for the associated device is not available. It will be appreciated that there can be several compatible device IDs for each logical device. The order of these device IDs within the compatible device ID field may be used as a criteria for determining which of the compatible device drivers should be searched for and loaded first.

The IRQ data field defines that the associated device uses an interrupt level and supplies a mask with certain bits set to indicate the levels implemented by the device. It will be appreciated that there are 16 possible interrupt levels for an ISA-compatible device.

The DMA data field indicates that the associated device uses a DMA channel and supplies a mask with certain bits set to indicate the channels actually implemented for the device.

The start and end dependent function fields express the interdependencies of the set of resources required by the associated device. The arbitrators 154 use the defined interdependencies to make resource allocation decisions for the logical device.

The I/O port descriptor field includes a full function descriptor for programmable ISA-compatible cards whereas, in contrast, the fixed location I/O port descriptor field supplies a minimal descriptor for existing ISA-compatible devices with fixed I/O requirements.

The Vendor defined field is an optional resource that may be defined for vendor-specific use.

The end tag identifies the conclusion of the resource data and includes a checksum covering all resource data presented after the serial identifier.

For the logical configuration data, Tables 4A-B show the preferred data structure and the information for the large information items of an ISA-compatible device.

TABLE 4A Offset Field Name Byte 0 Value = 1xxxxxxxB (Type = 1, Large item name = xxxxxxx) Byte 1 Length of data items bits [7:0] Byte 2 Length of data items bits [15:8] Bytes 3 Actual data items to n

TABLE 4B Large Item Name Value Memory range descriptor 0×1 Identifier string (ANSI) 0×2 Identifier string (Unicode) 0×3 Vendor defined 0×4 Reserved 0×5-0×7F

Turning now to Table 4A, the large configuration data type structure permits larger amounts of data to be included within the configuration data. Bit 7 of the first byte is set to one to differentiate the large item information from small item information. Bytes 1 and 2 define a 16-bit length field for data items, thereby enabling up to 64 kilobytes of actual data items. Bytes 3 through n include actual large item data, including fields for a memory range descriptor, an identifier string (ANSI), an identifier string (Unicode), and Vendor-defined data, as shown in Table 4B.

Referring to Table 4B and FIG. 1, the memory range descriptor field contains additional information about the characteristics of the memory on the device 20, such as memory control parameters, decode parameters, cache support, and write status. The memory range descriptor field further finds the minimum and maximum ranges for the base memory addresses, the base alignment bits, and the memory range length.

The ANSI identifier string field defines an 8-bit ANSI data string and the Unicode identifier string field defines a Unicode data string. The Vendor-defined data field is an optional data field for vendor use.

Detection of Dynamic Events

FIGS. 11A and 11B are logic flow charts illustrating tasks conducted by the configuration system in response to certain events affecting the operating state of a computer. FIG. 11A shows the configuration steps completed in response to the removal of an installed device from a system bus 18. In contrast, FIG. 11B shows the configuration steps taken in response to detection of the insertion of a new device on a system bus 18.

Referring now to FIGS. 6 and 11A, the process starts at step 269 in response to the enumerator 150 receiving an interrupt signal indicating the removal of one of the devices 20 on its assigned system bus 18. The enumerator 150 responds to detection of the device removal by reporting this dynamic event to the configuration manager 158 in step 270. The configuration manager 158 subsequently instructs the device driver 156 for this device in step 272 to terminate access for the removed device. In step 274, the configuration manager 158 instructs the arbitrators 154 to free the resource elements assigned to the removed device. In this manner, the resource elements previously assigned for use by the removed device become available for use by other devices 20 of the computer 8 as required by future configuration operations. In step 276, the configuration manager 158 unloads the device driver 156 corresponding to the removed device and this device driver 156 becomes available for use by other compatible devices. The process ends at step 277.

Turning now to FIGS. 6 and 11B, the process starts at step 278 and the enumerator 150 detects the connection of a new device to its assigned system bus 18 in step 280. The detection of this event is reported to the configuration manager 158 and, in response, the configuration manager 158 instructs the reporting enumerator 150 to enumerate the devices 20 on this affected system bus 18. In step 282, this enumerator 150 responds to the enumerate instruction by collecting device information from each of the devices 20 on the affected system bus 18. For the newly installed device, a device node corresponding to this device 20 is added to the hardware tree 152. In addition, if the new device represents a component which has not been previously installed with the computer 8, this new device information is stored in the registry 153.

Upon completion of the enumeration task, appropriate device drivers 156 are identified for use with the detected devices in step 284. The elements for the resources 14 are subsequently allocated in step 286 and the identified device drivers 156 are loaded in step 288. The process concludes at step 290. Thus, it will be appreciated that the above-described process enables the installation of a new device within the computer 8 without substantial intervention by the user.

In general, the enumerator 150 detects the insertion into or the removal of a device 20 from a socket or post of its assigned system bus 18 by either receiving an interrupt signal generated by the computer 8 or by pouring the system bus 18 on a systematic basis to determine the connected devices 20. For the ISA, PCMCIA, and certain docking busses, the associated enumerator receives an interrupt signal that signifies a change of device connections for the affected system bus 18. In contrast, for the SCSI bus and certain infrared link bus structures, it is necessary for the enumerator 150 to poll the associated esteem bus to determine whether a new device has been installed or an existing device removed from the polled bus.

Arbitrators

Arbitrator Elements

Turning now to a more detailed review of the tasks conducted by the arbitrators 154, FIGS. 12 and 13 respectively show the elements for a selected arbitrator 154 and the preferred steps for the arbitration process. Referring now to FIGS. 6 and 12, each arbitrator 154 is responsible for one of the resources 14 of the computer 8 and communicates with the configuration manager 158 via a bidirectional communications link to assign the elements of its particular resource 14.

During device configuration, the configuration manager 158 develops a possible working configuration based upon the device information for the devices 20 connected to the computer 8. For each resource 14, this possible configuration defines resource elements that have been defined as being necessary for operating the devices 20 with the computer 8.

For some of the devices 20, this possible configuration defines specific resource elements and, for others, the configuration describes general resource requirements. For example, if the arbitrator 154 is responsible for interrupts, a possible configuration for a modem defines specific interrupt elements, namely IRQ2 and IRQ3, whereas the configuration for another peripheral device may define a more general requirement for one of the set of interrupts supplied by the interrupt resource. Because the resource requirements for many of the devices 20 are general in nature, the configuration manager 158 often can supply alternative possible configurations as required to support the resource assignment activities of the arbitrator 154. Possible configurations are device dependent because they are developed by the configuration manager 158 in response to the resource requirements and resource dependencies for the identified devices of the computer 8. Thus, it will be appreciated that these possible configurations can be ordered by priority based upon the ranges for the specified resource requirements and the specific combinations of required resource elements.

The configuration manager 158 supplies a possible configuration to the selected arbitrator 154 to initiate the allocation of resource elements for a selected device. This possible configuration can be represented as an Assign-type instruction that defines the quantity and the range of resource elements for the designated device. For example, a typical instruction for the interrupt arbitrator is Assign (single IRQ, range=1-3, 5, and 9), which directs the assignment for a single interrupt within the range of a set of possible interrupts 1-3, 5, and 9. Another representative instruction for the memory arbitrator is Assign (start=2000h, end=6000h, size=32K, alignment=1), which directs the allocation of a 32k block of memory in the range of 2000h to 6000h.

To support the resource assignment tasks, each arbitrator 154 includes an analysis element 300 and an assignment element 302. In response to a possible configuration from the configuration manager 158, the analysis element 300 conducts an examination of the resource elements required by the designated device 20 to determine whether appropriate resource elements are available for use by that device. This analysis process is completed for each device 20 until the analysis element 300 locates appropriate resource elements for that device. However, in the event that the analysis element 300 determines that appropriate resource elements are not available for a selected device 20, then the analysis element 300 outputs a.i error flag to the configuration manager 158. In response, the configuration manager 158 supplies an alternative possible configuration to the analysis element 300 to support the allocation of the required resource elements for that device 20. This iterative analysis process will continue until resource elements are located by the analysis element 300 for each of the devices 20.

Upon identifying available resource elements, the arbitrator 154 supplies this resource element information to the assignment element 302. In response, the assignment element 302 assigns each resource element for use by the associated devices 20.

Each arbitrator 154 also maintains a table 304 defining assigned resource elements and a table 306 defining reserved resource elements. Upon the assignment of a resource element for a particular device 20, the assignment element 302 adds the assigned resource element as an entry to the assignment table. Thus, the assigned resource table 304 represents a list of the present resource element assignments for the installed devices 20 and each assigned resource element is matched to a corresponding device 20. These assignment entries are modified in response to the removal of an existing device or the insertion of a new device 20 for the computer 8. In addition, the assigned resource table 304 is rebuilt with new entries in response to powering the computer 8.

The reserved resource elements defined in the reserved resource table 306 represent resource elements that are reserved for assignment to certain known devices 20 that require selected resource elements. It is well known that certain devices 20 are designed to use particular elements of one or more of the resources 14. For example, a modem typically requires the use of the interrupts IRQ2 and IRQ3 and many printers are typically designed to use the interrupt IRQ7. Thus, it can be anticipated that certain devices 20 will require access to particular resource elements. Accordingly, for such known devices 20, particular resource elements are held in reserve for use if such devices are actually installed for use with the computer 8. The reserved resource table 306 contains the listing of such devices and their corresponding required resource elements. The initial entries for the reserved resource table 306 are preferably constructed and stored prior to the delivery of the operating system 10 to the end user.

The analysis element 300 preferably accesses the tables 304 and 306 during the determination of whether a particular resource element is available for use by one of the installed devices 20. This enables the analysis element 300 to determine whether a particular element of the resource 14 has been assigned or reserved for use by another device 20. For reserved elements defined in the reserved resource table 306, the analysis element 300 will generally assign those elements for use by only those devices 20 designated as rigidly requiring a specific resource element. Nevertheless, if the analysis element 300 has no other resource option, it may decide to assign a reserved element to a selected device 20 that is not designated as requiring a reserved resource.

The assigned resource table 304 can be stored within volatile memory because resource element assignments may change each time the computer 8 is powered. In contrast, the resented resource table 306 is preferably stored within nonvolatile memory to maintain an archival list of known devices 20 requiring the use of certain resource elements.

The assignment element 302 is also responsible for removing one or more entries from the assigned resource table 304. The assignment element 302 typically deletes a resource element assignment when an installed device 20 has been removed from the computer 8. In response to a “deallocate” instruction by the configuration manager 158. the assignment element deletes the resource assignments in the assigned resource table 304 for the designated device 20. This permits those resource elements to be assigned for use by other devices 20. A representative instruction for the memory arbitrator is the command Free (start=2000h, end=2200h), which clears the assignment for the allocated memory extending between 2000h and 2200h.

The steps for the arbitration process for a selected arbitrator 154 and its associated resource 14 are shown in FIG. 13. Referring now to FIGS. 6, 12, and 13, the arbitration process is started in step 320 in response to the analysis element 300 receiving a possible configuration from the configuration manager 158. In step 322, an inquiry is conducted by the analysis element 300 to determine for a selected device 20 whether a particular appropriate resource element has been assigned for use by another device 20. The analysis element 300 checks the resource assignments stored in the assigned resource table 304 to complete this inquiry. If the particular resource element is represented by an entry in the assigned resource table 304, then the “YES” branch is followed to the step 320 and the analysis process is initiated again based upon another possible configuration. In contrast, if the particular resource element has not been assigned, then the “NO” branch is followed from the step 322 to step 324.

In step 324, an inquiry is conducted to determine if the particular resource element has been reserved for use by another device 20. The analysis element 300 checks the reserved resource elements stored in the reserved resource table 306 to complete this inquiry. If the particular resource element is not reserved, then the “NO” branch is followed to step 328 and this element is assigned by the assignment element 302 for use by the selected device 20. This resource element assignment is stored in the assigned resource table 304 and supplied to the configuration manager 158. Upon assigning the appropriate resource element for the selected device 20, the arbitration process can then be started again for yet another device 20 based upon a new possible configuration for that device. This new possible configuration is supplied to the analysis element 300 by the configuration manager 158. However, in the event that the particular resource element has been reserved, then the “YES” branch is followed from step 324 to step 326.

The analysis process continues through step 326 by conducting an inquiry whether another appropriate resource element is available and is not reserved for use by another device 20. If so. the “YES” branch is followed from step 326 to step 328 and this element is assigned for use by the selected device 20. In contrast, if the response to this inquiry is negative, the “NO” branch is followed to the step 320 and another possible configuration is obtained from the configuration manager 158.

For the preferred configuration system. each arbitrator 154 is assigned to one of the resources 14 for the computer 8. As previously described, the resources 14 for a conventional personal computer include addresses for the memory 22, interrupts 24, DMA channels 26, and I/O ports 28. Nevertheless, it will be appreciated that the resources 14 also can represent any type of resource having a finite quantity of resource elements which can be assigned for use by multiple consumers.

For example, power consumption represents another type of resource because the power supply for a conventional personal computer is capable of supplying a finite amount of electrical power for use by the components of that computer. Thus, power consumption can be divided among multiple power consumers, specifically the active components of the computer. It will therefore be appreciated that an arbitrator 154 can be developed and used for the allocation and assignment of electrical power to the components of a computer to conserve power consumption.

Other examples of resources 14 include SCSI identification codes, device identification codes, and logical drive designations. Similar to the example for the power consumption arbitrator, it will be appreciated that the resource allocation concept of the arbitrators 154 can be extended to these type of resources.

Network System Configuration

A network system for a conventional general purpose computer is typically implemented by both hardware and software components. The hardware component is generally supplied by a peripheral device connected to a system bus of the computer. In general, the selected device is a network adapter card, commonly described as a network adapter, which is installed within the computer and connected via a wired or wireless communications link to the network system. The software component is generally supplied by an operating system adapted to supply network capabilities or by software routines supplied by the vendor of the associated network adapter. The adapted operating system can include multiple software routines, including protocols, redirectors, and servers, for implementing various network architectures. Similar to the hardware components of the computer, the network configuration routines also should be initialized and configured to support networking operations by the computer.

The network adapter, in combination with network configuration routines, operates on the computer to support the connection of the computer to a computer network. It will be appreciated that this combination of network hardware and software components enables the computer to accept a request from an application program running on the computer and to pass this request to another computer on the computer network. In turn, the remote computer can execute the request and return the results to the originating computer. Within this network environment, each computer is physically separate, runs its own operating system, and is connected to other computers of the network system via a wired or wireless communications link.

FIG. 14 is a block diagram that illustrates the hardware and software components for the preferred network system. Referring now to FIGS. 1 and 14, a network system 4(10 operates within the computing environment of the computer 8 and includes both network hardware and software components. The network hardware component is a selected device 20, specifically a network adapter 401, which is connected to the computer 8 via one of the system busses 18. For the described embodiment, the network adapter 401 is connected to an ISA bus supplied by the integrated bus 15. Nevertheless, it will be appreciated that the network adapter card 401 can be connected to other-system busses 18, including one of the interface busses 17 or 17′, such as the SCSI bus or the PCMCIA bus.

For the preferred operating system 10, each network adapter 401 is associated with one or more device drivers commonly described as network drivers 402 that operate within the shell of a network driver interface 403. A selected network driver 402, in combination with the network driver interface 403, enables the network adapter card 401 to communicate with the computer 8 and the operating system 10. Each network driver 402 can communicate directly with each network adapter 401 that it services by using the network driver interface 403 to access the driver's assigned cards. In addition, each network driver 402 can communicate with network configuration routines of the preferred operating system 10, specifically the protocols 404, via the network driver interface 403 to indicate data reception or completion of an outbound data transfer. Network drivers 402 are responsible for sending and receiving data packets over their respective network connection and for managing one or more network adapter cards on behalf of the operating system 10. This allows a selected network driver 402 to start I/O operations for its assigned network adapter 401 and to receive interrupts on behalf of this card.

The network driver interface 403 supports the design and implementation of network drivers 402 that are not dependent upon embedded knowledge of the CPU 12 or the operating system 10. In other words, the network driver interface 403 includes this platform-specific information to enable the network drivers 402 to be used with more than one operating system. In this manner, a single network adapter 401 and its corresponding network driver 402 is capable of communicating over multiple network configurations. For the preferred “WINDOWS” operating system, the network driver interface 403 is defined by a Network Driver Interface Specification (NDIS). Both network drivers 402 and the network driver interface 403 are generally known to those skilled in the art.

To implement one or more network configurations the operating system 10 also includes network configuration routines. such as protocols 404, redirectors 406, and servers 408. Each of the protocols 404, the redirectors 406, and the servers 408 is implemented as one or more software routines that support selected communications services for the network system 400. A selected set of one or more protocols 404, redirectories 406, and/or servers 408 form a network architecture or configuration that is “bound” to a corresponding network adapter 401.

The protocols 404 operate to format messages for transmission via the network system 400 and communicate with (1) the network adapter 401 via the interface 412 and with (2) the redirectors 406 and the servers 408 via interfaces 414. Typical protocols 404, which are also described as transports or transport protocols, include the Net BIOS Extended User Interface (NetBELUI), Transmission Control Protocol/Internet Protocol (TCP/IP) (the “IP protocol”), Internet Packet Exchange/Sequenced Packet Exchange (IPX/SPX) (the “IPX” protocol”), DECnet, AppleTalk, and Xerox Network Systems (XNS).

The redirectors 406 generally operate to direct I/O requests to remote file systems or devices and supply the facilities necessary for the computer 8 to access resources on other computers via the network system 400. For example, when an user or application program issues an I/O request destined for a remote file, directory, or machine, this request is supplied to a selected redirector 406 which, in turn, “redirects” the request to a remote server via the communications link network system 400. For the preferred operating system 10, each redirector 406 is preferably implemented as a file system driver and communicates with one or more of the protocols 404 via an interface 414. Redirectors 406 include the Service Message Block (SMB) redirector and the Netware Core Protocol (NCP) redirector, which are supplied by Microsoft Corporation for its “WINDOWS” operating system.

Each server 408 operates to accept requests from a process on another machine connected to the network system 400 rather than from a process on the computer 8. In other words, the servers 408 allow other computers or machines on the computer network to access a file or a directory on the computer 8. Similar to the redirectors 406, each server 408 communicates with one or more of the protocols 404 via an interface 414. Servers 408 include the SMB server offered by Microsoft Corporation for its “WINDOWS” operating system.

For the Open Systems Interconnections (OSI) reference model for network systems, it will be appreciated that the protocols 404 generally correspond to the data link, network, and transport layers on a client machine, the redirectors 406 correspond to the session, presentation, and application layers on the client machine, and the servers 408 correspond to the session, presentation, and application layers on the server machine.

FIG. 15 is a simplified block diagram supplying a hierarchical view of certain hardware and software components of a network system. Referring now to FIGS. 1 and 15, the network adapter 401 represents a selected device 20 that is connected to one of the system busses 18, namely, the integrated bus 15. For the network architecture shown in FIG. 15, the network adapter 401 is configured for operation with three separate protocols 404, the IP, IPX, and NetBEUI protocols. The NetBEUI protocol operates in conjunction with a single redirector 406 and server 408, namely the SMB redirector and the SMB server. The IPX protocol operates with a pair of redirectors 406, specifically the SMB and NCP redirectors. and the IP protocol operates with a single redirector 406, the SMB redirector. It will be appreciated that the network architecture of FIG. 15 is merely one example of numerous possible network architectures and that the present invention is not limited to this specific example. However, the network architecture shown in FIG. 15 will be used to illustrate the novel features of the present invention.

The connection of the network adapter 401 to the integrated bus 15 forms a physical electrical connection between these hardware components. In contrast, data communications between the network adapter 401 and the protocols 404 compatible with this card are carried via a communications link implemented by one or more software routines, specifically the interface 412. Likewise, data communications between the protocols 404 and the redirectors 406 and servers 408 are conducted via software-implemented communications links, specifically the interfaces 414. To emphasize the hierarchical architecture of the network configuration routines, the communications links supplied by the interfaces 412 and 414 have been simplified in the illustration of FIG. 15 by showing a “direct” connection between the network adapter 401 and the protocols 404 and “direct” connections between the protocols 404 and the associated sets of redirectors 406 and servers 408. It will be understood that the interface 412 can include the assigned network driver 402 (FIG. 14) and the network device interface 403 (FIG. 14).

Specifically, the hierarchical architecture of the network system 400 in FIG. 15 illustrates logical connections that must be implemented for the network system 400 to operate within the computer 8 (FIG. 1). The interface 412 represents communications between the protocols 404 and a network driver 402 (FIG. 14) supporting a network adapter 401. For example, the network driver 402 can use network driver interface 403, such as NDIS 2.0 or NDIS 3.1, or an ODI interface, to communicate with the protocols 404 For the preferred embodiment, the logical connection between the network adapter 401 and the protocols 404 is implemented by a network driver 402 and the network driver interface 403 (NDIS 3.1). Each protocol 404 can communicate with a selected set of the redirectors 406 and the servers 408 via a dedicated interface 414. For the network architecture in FIG. 15, the IP, the IPX, and the NetBEUI protocols are associated with the same interface, the interface 412, for communication with the network adapter 401. In contrast, a separate interface 414 can extend between each of the protocols 404 and their respective redirectors 406 and servers 408. In particular, the protocol to redirector and/or server interfaces, i.e., the interfaces 414, vary according to the components connected by these logical connections. For example, the SMB redirector preferably uses the NetBIOS interface to communicate with the NetBEUI and IP protocols, and can communicate with the IPX protocol via the NWLink interface or the NetBIOS interface. The NCP redirector preferably uses the NWLink interface to communicate with the IPX protocol. Accordingly, it will be understood that a single interface 412 extends between a selected network adapter 401 and the protocols 404, whereas multiple interfaces 414 are used for communications between the protocols 404 and their respective set of redirectors 406 and servers 408.

To extend the “plug and play” concept from the hardware domain to the network software domain, the protocols 404, the redirectors 406, and the servers 408 can be viewed as software layers or “virtual devices” and the interfaces 412 and 414 can be viewed as “virtual busses.” The protocols 404 represent a first set of layers “connected” to the network adapter 401 via the interface 412. In turn, each of the protocols 404 is “connected” via one of the interfaces 414 to a second set of layers comprising the redirectors 406 and the servers 408. For the purposes of this application, the term “layer” is used interchangeably with the term “virtual device” as a general term describing the network configuration routines of the protocols 404, redirectors 406, and servers 408. Thus, it will be understood that each of the protocols 404, the redirectors 406, and the servers 408 represent individual layers of the network system 400.

Based upon this hierarchical view of the network software components, a software configuration system analogous to the previously described device configuration system is supplied by the present invention. The device configuration system detects the presence of the devices 20 on each of the system busses 18, allocates resources to each of the detected devices, and directs the automated loading of device drivers for the detected devices. Likewise, the software configuration system can identify the virtual devices for each of the virtual busses of the network system 400 and automatically load the drivers that support the identified virtual devices.

It will be appreciated that the network configuration routines for the virtual devices or layers of the network system 400 require configuration to support their proper operation with a selected network adapter 401. Automation of the configuration process supplies the advantage of removing the user from these configuration tasks. In general, this configuration process includes identifying the appropriate protocols 404, redirectors 406, and servers 408 for use with the selected network adapter 401 and, in turn, loading these software routines. The loading process can be viewed as a two-step process of loading the drivers for these routines within the memory 22 (FIG. 1) and thereafter configuring the drivers by supplying configuration parameters.

Referring now to FIGS. 6, 14, and 15, the configuration system for the network system 400 is based upon the assignment of an enumerator to each of the system busses 18 and to the interfaces 412 and 414. However, in contrast to the system busses 18, the same network enumerator is assigned to both the interface 412 and the interface 414. Specifically, the network driver interface 403 preferably operates as an enumerator and is responsible for the identification of each of the network configuration routines associated with these interfaces.

In response to a command from the configuration manager 158, the network driver interface 403 operates as an enumerator for the interface 412 and identifies each of the protocols 404 on that interface. This identification process is conducted by locating in the registry 153 information that defines the protocols 404 for use with the network adapter 401. To maintain a current record of installed network configuration routines, the identities of the defined protocols are thereafter stored within device nodes of the hardware tree 152. In response to the identification of the protocols 404, software drivers are loaded by the network driver interface 403 and configured to enable the operation of these layers within the network system 400. In turn, the network driver interface 403 operates as an enumerator for each of the interfaces 414 and locates within the registry 153 information that defines the identities of the corresponding redirectors 406 and servers 408. The identities of the detected redirectors 406 and servers 408 for the interfaces 414 are then stored within the hardware tree 152. In turn, drivers for the identified redirectors 406 and servers 408 are loaded and configured based upon entries stored within the registry 153.

Although the entries within the registry 153 for the network configuration routines will be described in more detail below with respect to FIG. 17, it will be appreciated that these entries are based upon a priori knowledge about the appropriate network software configurations for selected network adapters. In other words, these registry entries can be created and stored prior to starting the configuration of the network system 400. The network setup/control panel program, also referred to as the Net Setup routine, is responsible for creating and maintaining the information stored within the registry 153. In particular, the Net Setup routine supplies the capability for the user to create and modify the registry entries for network configurations.

For the preferred embodiment, upon powering the computer 8, the devices 20, including each network adapter 401, are detected and allocated resource elements. The device drivers 156 are then loaded for the detected devices. In response to loading a particular type of device driver, specifically one of the network drivers 402, the network software configuration process is initiated by the configuration manager 158 issuing an enumerate command to the enumerator for the interface 412, the network driver interface 403. Accordingly, the installation of a network adapter card as one of the devices 20 within the computer 8 serves as the catalyst for configuring the network software routines at boot time. Likewise, the network software configuration process can be initiated as a result of the insertion of a network adapter card 401 when the computer is powered or upon the docking of the computer to its docking station.

In addition, it will be appreciated that the network adapter 401 can be removed during operation of the computer 8. thereby affecting the configuration of the network system 400. For example. a network adapter 401 compatible with the PCMCIA bus is designed for easy insertion and removal by the user. The removal of this type of network adapter card supplies no advance warning of card removal to the operating system 10. Instead, the connection between the network adapter 401 and the PCMCIA bus is broken and the configuration manager 158 thereafter receives an interrupt indicating a change in status for that bus slot. For this “surprise style” card removal, the network driver 402 for this network adapter 401 is preferably unloaded by the operating system 10 if there are no other network adapter cards of this model in use by the computer 8. In addition, the protocols 404, redirectors 406, and servers 408 configured for operation with this network adapter 401 can receive failure codes or error messages whenever these software components attempt to access the removed adapter. In addition, the user interface for the preferred operating system 10 can supply a text-based message or audible warning upon detection of this surprise style card removal.

In contrast, for a docking-type computer, the user typically can warn the operating system 10 about an impending change in the status of the network adapter 401 prior to the removal of the computer from its docking station. Accordingly, this type of computer 8 can be released from the docking station upon the acquiescence of this event by all networking software components. This type of removal is described as a “VCR style” removal. In response to notice of an impending undocking operation, each network software component can close remote files, flush any caches, and close connections prior to the release of the computer from the docking station. Each of the protocols 404, redirectors 406, and servers 408 represented by device nodes in the hardware tree 152 receives this notice. After each network software component responds to this notice, these network software components and the network driver 402 can be unloaded.

In view of the foregoing, it will be useful to review the steps of the network configuration process. FIG. 16 is a logical flow diagram that illustrates the steps for a process of configuring the network software components of a network system. Referring now to FIGS. 6, 15, and 16, the process is initiated at the START step and proceeds to step 420 to select an interface for a selected network adapter 401 configured for operation with the computer 8. For the preferred embodiment, this network adapter card has received an allocation of the appropriate resources 14 and a device driver, namely a network driver 402, has been loaded to support communications between the card and the computer 8. For the initial pass through the steps of this iterative process, the interface 412 between the network adapter 401 and the protocols 404 is selected.

In step 422, the layers for the interface 412 are identified based upon information stored within the registry 153. Entries within the registry 153 define various configurations of the protocols 404, the redirectors 406, and the servers 408 that are compatible with the selected network adapter 401. These entries will be described in more detail below with respect to FIG. 17. For this initial pass, the protocols 404 associated with the interface 412 are identified based upon the registry entry for the network adapter 401.

In response to the identification of the layers, in step 424, the drivers for these identified layers are loaded within the memory 22. To complete the loading of the identified layers, configuration parameters stored in the registry 153 are supplied to the loaded drivers in step 426. In this manner, the identified layers are loaded to support the operations of the selected network adapter 401 in the network system 400. Entries within the registry 153 identify the driver for the identified layers and define the configuration parameters for these drivers. Configuration parameters are assigned based upon the corresponding drivers. For this initial pass, the drivers for the protocols 404 are loaded in step 424 and the configuration parameters for these drivers are supplied in step 426.

In step 428, an inquiry is conducted to determine whether the configuration for the selected network adapter 401 includes additional interfaces. If so, the “YES” branch is followed to step 420 and another interface is selected. Because each of the protocols 404 uses a separate interface 414 to communicate. with the upper layers of the redirectors 406 and the servers 408, this loop will be repeated until all of the interfaces 414 are selected and the associated upper layers are identified, loaded, and configured. In contrast, if the response in step 428 is negative, the “NO” branch is followed from step 428 to the END step and the process is terminated. This network configuration process will be described in more detail below with respect to FIG. 19.

Although the process has been described with respect to the network architecture of FIGS. 14 and 15, it will be appreciated that this process can be extended for configuring other network architectures. Specifically, the present invention is not limited to the illustrated example of protocols 404, redirectors 406, servers 408, or interfaces 412 and 414. Accordingly, it will be appreciated that the present invention is also applicable to a network configuration including a variety of network configuration routines and their associated software implemented communications links. However, regardless of the network configuration, the same enumerator, i.e., the network driver interface 403, is preferably used to enumerate all interfaces.

FIG. 17 is a diagram that supplies a high level view of the network system-related entries stored within the archival memory of the registry 153 for the network configuration shown in FIG. 15. Referring now to FIGS. 6, 15, and 17, the registry 153 contains entries that define network configurations of the software components for various types or models of network adapters 401. To support configuration operations for the network configuration routines, the registry 153 preferably contains three types of entries, first and second entries 432 and 434 stored under the hardware archive 184, and a third entry 436 stored within the software archive 182. Although the registry 153 shown in FIG. 17 contains only network-related entries, it will be understood that the registry 153 also includes entries for other hardware and software components that have been or are presently installed for operation with the computer 8. Thereafter, although FIG. 17 supplies a representative example of registry entries for a network system, it will be understood that the present invention is not limited to this described example and can support numerous network configurations.

The first entry 432 is directed to one of the interfaces 412 and 414 of the network system 400 and is identified by an interface identification code that is uniquely associated with the corresponding interface. The interface identification code comprises (1) an interface name which uniquely identifies the interface and (2) an instance number. For the interface 412, the first entry 432 is identified by an interface identification code having an interface name that identifies a selected network adapter 401 and an instance number useful for distinguishing between multiple cards of the same model for this network adapter. Preferably, this interface identification code for the interface 412 is identical to the identification code assigned to the selected network adapter 401. As previously described, the identification code for a device 20 can represent the manufacturer's identity, the model of the corresponding device, and the instance number.

If the network system 400 includes more than one interface 414, then each of these interfaces has a corresponding first entry 432 within the registry 153. For each interface 414, the first entry 432 includes (1) an interface identification code having an interface name that identifies one of the protocols 404 which is compatible with the selected network adapter 401 and (2) an instance number to distinguish between multiple versions of this protocol.

In addition, the first entry 432 can include at least one layer identification code that defines the identity of a corresponding layer. The layer identification code comprises (1) a layer name that uniquely identifies the corresponding layer and (2) an instance number. For the interface 412, the layer identification code can include a layer name which identifies one of the protocols 404 that is compatible with the network adapter 401. In contrast, for the interface 414, the first entry 432 can include a layer identification code having a layer name identifying one of the redirectors 406 or the servers 408 required for the network configuration. Each layer identification code in a first entry 432 can be used as a key to locate a corresponding second entry 434 in the registry 153.

In view of the foregoing, it will be appreciated that the interface 412 is associated with a network adapter 401, whereas each interface 414 is associated with a corresponding protocol 404. In addition, each protocol 404 can operate as a software layer of the network system 400. Thus, a protocol 404 can operate both as a virtual bus and as a virtual device. Specifically, the protocol 404 operates as a virtual device connected to a network adapter 401 via the interface 412 and, in addition, operates as a virtual bus providing a connection for one or more redirectors 406 and servers 408 via an interface 414.

Each of the second entries 434 is directed to one of the layers of the network system 400 and is identified by the layer identification code corresponding to its associated layer. Accordingly, each of the protocols 404, redirectors 406, and servers 408 is assigned a unique layer identification code. Each second entry 434 also can include a driver identification code that defines a driver for the associated layer. The driver identification code comprises a driver name that uniquely identifies the corresponding driver and an instance number to distinguish between multiple drivers of the same model or type. This driver identification code within a second entry 434 serves as a pointer to one of the third entries 436, which are located within the software archive 182.

Each third entry 436 is identified by a corresponding driver identification code. A portion of each third entry 436 typically contains configuration parameters for the driver of the associated layer. For example, the driver for the IP protocol can include a configuration parameter for the IP Address, while the driver for the EPX protocol has a configuration parameter for the FrameType. These configuration parameters are dependent upon the corresponding drivers.

In view of the foregoing, it ,%i be understood that the hardware archive 184 of the registry 153 includes additional tree-like device branches for each network adapter 401 that has been installed for past or present operations of the computer 8. Each device branch for a network adapter card extends from one of the enumerator branches connected to the ENUM branch 186 within the hardware archive 184. The hardware archive 184 also can include a NETWORK branch 442, which extends from the ENUM branch 186. This branch represents the enumerator 150 assigned to the interfaces 412 and 414, namely the network device interface 403. The NETWORK branch 442 can include layer branches representing layer-related information for the network configuration routines.

For the network architecture shown in FIG. 15, the registry 153 includes a device branch 440 representing the detected network adapter 401 (DEC DEPCA) and extending from the IS.AEN-i enumerator branch 192. The device branch 440 represents a first entry 432 and indicates that a selected network adapter 401 has operated in the past or is presently installed on the ISA bus of the computer 8. It will be understood that the registry 153 can include additional device branches representing other network adapter cards installed for operation on the ISA bus or on one of the remaining system busses 18. Table 5 supplies an example of the registry entry for the network adapter 401, specifically the DEC DEPCA network adapter card.

TABLE 5

*PNP80E7\

 0000\

DeviceDesc=DEC DEPCA

Class=Net

Driver=Net\0000

Bindings\

NETBEUI\000=

MSTCP\0000=

NWLINK\0000=

Referring to Table 5, which represents the network adapter-related information stored under the device branch 440 of the registry 153, the network adapter 401 is identified by the identification code “*PNP80E7\000,” wherein “*PNP80E7” represents the name of the device and the appended “\0000” is the instance number for this device. Thus, this registry entry represents the first instance of the DEC DEPCA card for the computer 8. The registry entry for the network adapter 401 includes at least four data fields, including “DeviceDesc,” “Class,” “Driver.” and “Bindings.” The first three data fields generally describe operating characteristics for the selected device 20, in this case the network adapter 401, by identifying the model name (DEC DEPCA), the primary operating function (Net, i.e., Network), and Driver (Net\0000). In addition, the registry entry includes the Bindings subkey which identifies the protocols 404 that are bound to this card and support its network configuration. For this example, the protocols 404 include the NetBEUI protocol (NETBEUI\0000), the IP protocol (MSTCP\0000), and the IPX protocol (NWLINK\000). Each entry below the Bindings subkey represents a layer identification code for one of the protocols 404 associated with the identified network adapter card. Thus, the network configuration for this card includes the protocols 404 identified by the layer identification codes of the Bindings subkey.

Layer branches 444-451, which extend from the NETWORK branch 442, are examples of typical layer branches and represent the protocols 404, redirectors 406, and servers 408 that support possible configurations of the network system 400. For the network configuration in FIG. 15, the registry 153 includes at least eight layer branches, specifically the layer branches 444, 445, and 446 for protocols 404, layer branches 447, 448, 449, and 450 for redirectors 406, and layer branch 451 for a server 408. The layer branches 444, 445, and 446 represent both first entries 432 and second entries 434 because protocols 404 can implement both virtual devices and virtual busses. In contrast, the layer branches 447, 448, 449, 450, and 451 represent second entries 434.

The layer branches 444, 445, and 446 respectively contain information about the NetBEUI, IP, and IPX protocols. For each of the protocols 404, the information supplied by its corresponding layer branch generally (1) describes the identified protocol, (2) identifies the driver for this protocol, and (3) defines the specific redirectors 406 and servers 408 required to complete the network configuration. Tables 6-8 supply examples of the registry entries for the NetBEUI, IP, and IPX protocols.

TABLE 6 NETBEUI\ 0000\ DeviceDesc = Microsoft NetBEUI CompatibleIDs = NETBEUI Class = NetTrans Driver = NetTrans\0000 ConfigFlags = 00 00 00 00 Bindings\ VREDIR\0000 VSERVER\0000

TABLE 7 MSTCP\ 0000\ DeviceDesc = Microsoft TCP/IP CompatibleIDs = MSTCP Class = NetTrans Driver = NetTrans\0001 ConfigFlags = 00 00 00 00 Bindings\ VREDIR\0001

TABLE 8 NWLINK\ 0000\ DeviceDesc = Microsoft IPX/SPX-compatible CompatibleIDs = NWLINK Class = NetTrans Driver = NetTrans\0002 ConfigFlags = 00 00 00 00 Bindings\ NWREDIR\0000 VREDIR\0002

Reviewing the registry entry for a protocol 404 (NetBEUI protocol) shown in Table 6, the interface identification code, as well as the layer identification code, for the NetBEUI protocol is “NETBEUI\0000,” wherein the layer name is “NETBEUI” and the instance number is “0000.” This entry represents the first instance of the NetBEUI protocol within the registry 153. The data field “DeviceDesc” describes the type of device and, in this case, defines the layer as a Microsoft NetBEUI protocol. The “CompatibleIDs” data field identifies the compatible identification code as “NETBEUI.” The “Class” data field indicates that the NetBEUI protocol is classified as a protocol 404, specifically a “NetTrans”-type layer. The driver for this instance of the NetBEUI protocol is defined by the “Driver” data field and is identified by the driver identification code “NetTrans\0000.” The configuration flags in the “ConfigFlags” data field are set to zero. The configuration flags are indicators for the present operating state of the device. For example, the configuration flags can be set to designate the following states: (1) the device is present and running; (2) the device is present but not to be used; or (3) the device was once configured, but is now removed from the computer. The “Bindings” subkey can supply one or more additional layer identification codes to identify the redirectors 406 and the servers 408 required to complete the network configuration. In this example, the SMB redirector is identified by the layer identification code “VREDIR\0000” and the SMB server is identified by the layer identification code “VSERVER\0000.”

The data structure for the registry entries shown in Tables 7 and 8 are similar to the data structure of the NetBEUI protocol in Table 6.

The layer branches 447, 448 and 449, which are respectively identified by the layer identification codes “NREDIR\0000”, “VREDIR\0001,” and “VREDIR\0002” contain information about three instances in the registry 153 of the SMB redirector. The layer branch 450. which is identified by the layer identification code “NWREDIR\0000.” contains information about the NCP redirector. This stored information generally describes each identified redirector and identifies the driver for this network configuration routine. Tables 9 and 10 supply examples of registry entries for the SMB and NCP redirectors.

TABLE 9 VREDIR\ 0000\ DeviceDesc = Microsoft SMB Redirector CompatibleIDs = VREDIR Class = NetClient Driver = NetClient\0000 ConfigFlags = 00 00 00 00 Bindings\

TBALE 10 NWREDIR\ 0000\ DeviceDesc = Microsoft NCP Redirector CompatibleIDs = NWREDIR Class = NetClient Driver = NetClient\0001 ConfigFlags = 00 00 00 00 Bindings\

Reviewing the registry entry for a redirector 406 (SMB redirector) in Table 9, the interface identification code for the SMB redirector is “VREDIR\0000,” wherein the layer name is “VREDIR” and the instance number is “0000.” This entry represents the first instance of the SMB redirector within the registry 153. The data field “DeviceDesc” defines the layer as a Microsoft SNEB redirector. The “Compatible IDs” data field identifies the compatible identification code as “VREDIR.” The “Class” data field indicates that the SMB redirector is classified as a redirector 406, specifically a “NetClient”-layer. The driver for the SMB redirector is defined by the “Driver” data field and is identified by the driver identification code “NetClient\0000.” The configuration flags in the “ConfigFlags” data field are set to zero. The “Bindings” subkey does not list additional layers that are associated with this instance of the SMB redirector.

The data structure for the registry entry shown in Table 10 is similar to the data structure of the SMB redirector in Table 9.

The layer branch 451 identified by the layer identification code “VSERVER\0000” contains information about the SMB server in the registry 153. This branch contains information that generally describes the identified server and defines the driver for this network configuration routine. Table 11 supplies an example of a registry entry for a SMB server.

TABLE 11 VSERVER\ 0000\ DeviceDesc = Microsoft SMB Server CompatibleIDs = VSERVER Class = NetServer Driver = NetServer\0000 ConfigFlags = 00 00 00 00 Bindings\

As shown in Table 11, the data fields for the registry entry for a server 408 are similar to the data fields for registry entries associated with redirectors 406 (Tables 9 and 10). In view of the foregoing, Table 11 represents a registry entry containing information about the first instance of a SMB server. The driver for this server is identified by the driver identification code “NetServer\0000.” Similar to the registry entries for the redirectors, the Bindings subkey for this entry does not define additional layers connected to this server. This is in contrast to the registry entries for protocols 404, which typically list one or more layer identification codes below the Bindings subkey to identify associated layers.

Focusing now on the software archive 182 in FIG. 17, a CLASS branch 460, which represents the classes of device drivers and drivers for the operating system 10, extends from the root of the software archive 182. The CLASS branch 460 also can include driver branches representing driver-related information for the network configuration routines. As previously described, the driver identification codes supplied by the device branches extending from the NETWORK branch 442 operate as pointers to associated driver branches on the CLASS branch 460. Each of the driver branches extending from the CLASS branch 460 represent third entries 436 for the registry 153.

For the network architecture shown in FIG. 15, the registry 153 includes a driver branch 461, which represents the driver for the network adapter 401 identified by the device branch 440 of the hardware archive 184. The driver branch 461 is identified by the device identification code “Net\0000” and contains configuration parameters for a network driver 402. It will be understood that the registry 153 can include additional driver branches representing device drivers for other network adapter cards on the ISA bus or on one of the remaining system busses 18. Table 12 supplies an example of the registry entry for the network driver 402 that supports a selected network adapter 401, i.e., the DEC DEPCA card for the network configuration of FIG. 15.

TABLE 12 \SYSTEM\CurrentControlSet\Services\Class\ Net\ = Network Adapter Installer = netdi.dll Icon = 0 0000\ DeviceDesc = DEC DEPCA DevLoader = ndis.386 DeviceVxDs = declan.386 MaxMulticast = 8 MaxTransmits = 16 AdapterName = DEPCA NDIS\ LogDriverName = LANCE MajorNdisVersion = 03 MinorNdisVersion = 0A NDIS2\ DriverName = DEPAS FileName = depca.dos ODI\ DriverName = DEPCAODI FileName = depcaodi.com

Referring to the Table 12, a registry entry is shown for the network driver 402 that supports the DEC DEPCA network adapter card. The driver identification code for the driver is “Net\0000,” the driver name is “Net” and the instance number is “0000.” This entry represents the first instance of a driver for a particular network adapter 401, namely, the DEC DEPCA network adapter card. The data field “Installer” defines the routine that is to be used when installing or removing this device from the computer. The “Icon” data field defines an index of an icon that represents the device on a display screen. The data field “DeviceDesc” indicates that the driver is intended for primary use with the DEC DEPCA network adapter card. The “DevLoader” data field defines the device loader for this driver, specifically the network driver interface 403, which is also described as the “ndis.386” device loader. The “Device V×Ds” data field describes the actual file name(s) of the driver for this device. The “MaxMulticast” data field defines the number of multicast addresses that will be maintained for the device. The “MaxTransmits” data field defines the maximum number of simultaneous transmissions that can be attempted by the device. The “AdapterName” field defines a label for the device and is used internally within the NDIS interface.

The NDIS subkey within the registry entry of Table 12 provides information that is specific to configuring different variants for the device driver of this device, specifically the network adapter card 401. These variants include the NDIS 3.1 and NDIS 2.0 interfaces and the ODI interface. The data field “LogDriverName” defines a label for use internally by the NDIS interface to identify the driver the for the network adapter card. The “MajorNdisVersion” and the “MinorNdisVersion” data fields in combination define the supported NDIS interface level. (“03” and “0A” define the level 3.1). The NDIS2 subkey provides specific information for configuring the NDIS 2.0 device driver. Likewise, the ODI subkey provides specific information for configuring the ODI device driver. The “DriverName” data field defines a label that is used internally by the corresponding interface to indicate the device driver. The “FileName” data field defines the actual file name(s) of the corresponding device driver.

Driver branches 462-467, which extend from the CLASS branch 460 of the software entries 182, are examples of typical driver branches and represent drivers for the protocols 404, redirectors 406. and servers 408 that support possible configurations of the network system 400. For the network configuration in FIG. 15, the registry 153 includes at least six driver branches, specifically the driver branches 462, 463, and 464 for protocols 404, driver branches 465 and 466 for redirectors 406, and driver branch 467 for server 408. Each of these driver branches 462-467 represent third entries of the registry 153.

The driver branches 462, 463, and 464 respectively contain information about the drivers for the NetBEUI, IP, and IPX protocols represented by the device branches 444, 445, and 446. For example, for the device branch 444, the registry entry for the NetBEUI protocol (Table 6) includes a “Driver” data field containing the device identification code “NetTrans\0000,” which serves as a pointer to the driver branch 462 identified by that driver identification code. Tables 13. 14, and 15 supply examples of the registry entries for the drivers for the NetBEUI, IP, and IPX protocols.

TABLE 13 NetTrans\ = Network Transport Installer = netdi.dll Icon = 1 0000\ DeviceDesc = Microsoft NetBEUI DevLoader = ndis.386 DeviceVxDs = netbeui.386 NDIS\ LogDriverName = NETBEUI MajorNdisVersion = 03 MinorNdisVersion = 0a NDIS2\ DriverName = NETBEUI FileName = *netbeui

TABLE 14 NetTrans\0001\ DeviceDesc = Microsoft TCP/IP DevLoader = ndis.386 DeviceVxDs = vtdi.386, vip.386, vtcp.386. vnbt.386 IP Address = 101.2.0.2 NDIS\ LogDriverName = MSTCP MajorNdisVersion = 03 MinorNdisVersion = 0a

TABLE 15 NetTrans\0002\ DeviceDesc = Microsoft IPX/SPX-compatible DevLoader = ndis.386 DeviceVxDs = nwlink.386 NetAddress = 11111111 FrameType = 0 NDIS\ LogDriverName = NWLINK MajorNdisVersion = 03 MinorNdisVersion = 0a NDIS2\ DriverName = nwlink$ FileName = nwlink

Reviewing the registry entry shown in Table 13, the driver identification code for the driver for the NetBEUI protocol is “NetTrans\0000,” wherein the driver name is “NetTrans” and the instance number is “0000.” This entry represents the first instance of a driver for the NetBEUI protocol. The data field “Installer” defines the routine for installing or removing the device.

The “Icon” data field defines the index of an icon for representing the device on a screen display. The data field “DeviceDesc” indicates that the driver is intended for primary use with the Microsoft NetBEUI protocol. The “DevLoader” data field defines the device loader for this driver, the ndis.386 device loader. The data field “DeviceV×Ds” defines the actual file name(s) of the driver for this device. The NDIS subkey provides information that is specific to configuring different variants of the device driver. The “LogDriverName” data field defines a label used internally by the NDIS interface to identify the driver for the associated layer, i.e., the NetBEUI protocol. The “MajorNDISVersion” and “MinorNDISVersion” data fields in combination define the level of supported NDIS interface. (“03” and “0A” define level 3.1). The NDIS 2 subkey provides specific information for the driver of the NDIS 2.0 interface. The “DriverName” data field defines a label that is used internally within the NDIS 2 interface to define the device driver. The “FileName” data field defines the actual file name(s) of the device driver for the NDIS 2.0 interface.

The data structures for the registry entries shown in Tables 14 and 15 are generally similar to the data structure of the driver for the NetBEUI protocol in Table 13. However. the registry entry in Table 14 for the data structure of the driver for the IP protocol includes the configuration parameter IP Address. In addition, the registry entry in Table 15 for the data structure of the driver for the IPX protocol includes configuration parameters for “NetAddress” and “NameType” data fields.

The driver branches 465 and 466, which are respectively identified by the driver identification codes “NetClient\0000” and “NetClient\0001,” respectively contain information about drivers for the SMB redirector and the NCP redirector. Tables 16 and 17 supply examples of the registry entries for these drivers.

TABLE 16 NetClient\ = Network Client Installer = netdi.dll Icon = 2 0000\ DeviceDesc = Microsoft SMB Redir DevLoader = ndis.386 DeviceVxDs = vredir.386

TABLE 17 NetClient\0001\ DeviceDesc = Microsoft NCP Redir DevLoader = ndis.386 DeviceVxDs = nwredir.386

TABLE 18 NetServer\ = Network Server Installer = netdi.dll Icon = 3 0000\ DeviceDesc = Microsoft SMB Server DevLoader = ndis.386 DeviceVxDs = vserver.386

Tables 5-18 illustrate examples of network system-related information stored within the registry 153 for the network configuration shown in FIG. 15. In view of these representative entries, it will be recognized that the first entries 432 support the identification of layers for the associated interface, the second entries 434 define the driver for the identified layer, and the third entries 436 include configuration parameters for the identified driver. Accordingly, each of these entries contains information relevant to the tasks of identifying and loading layers for each interface of the network system 400. Nevertheless, it will be understood that the present invention is not limited to the examples of the registry entries shown in Tables 5-18, nor is the present invention limited to the network architecture shown in FIG. 15.

Still referring to FIGS. 6, 15, and 17, a one-to-one correspondence between the device branches 444-451 and driver branches 461-467 is not available because at least one of the network drivers 402 represented by a registry entry in the software archive 182 is useful for supporting two or more of the network configuration routines represented by the registry entries stored within the hardware archive 184. Those skilled in the art will recognize that a device driver can be used to support both a primary device ancrcompatible devices. For the example of the network configuration in FIG. 15, the driver for the “SMB redirector,” which is represented by the driver branch 465, is useful for supporting the SMB redirectors represented by the device branches 447, 448, and 449.

For the preferred operating system 10, the registry 153 includes first, second and third entries 432, 434, and 436 to support the installation of a default network configuration for a network adapter 401 installed within the computer 8. A “default” network configuration includes the NetBEUI protocol associated with the SMB redirector and the IPX protocol associated with both the NCP and SMB redirectors. Accordingly, the registry 153 typically will contain certain entries for network configuration routines that are defined and stored prior to the shipment of the operating system 10 to the purchasing public.

The creation of the first, second, and third entries 432, 434, and 436 can be triggered either by automatic device detection at installation, boot, dock/undock, or PCMCIA card insertion/removal time, or at any time when the user explicitly uses the network control panel to create these registry entries. To add network configuration routine-related entries to the registry 153, a “Net Setup” routine (not shown) of the operating system 10 can access a .INF file corresponding to the selected network adapter 401. The .INF file, which is preferably stored within nonvolatile memory of the computer 8, is identified by the interface identification code assigned a selected network adapter card 401 and contains information describing this card, including the network configuration routines. The Net Setup routine can transfer this information to the archival memory of the registry 153 to add the new registry entries.

As previously described, the hardware tree 152 contains a set of device nodes that represent the present configuration of the devices 20 operating with the computer 8. For the devices 20, each device node represents one of the devices presently installed for operation with the computer 8 and contains device attributes, including device identity, resource usage requirements, and resource assignments. In addition, the hardware tree 152 supplies a hierarchical representation of the identities for the present network configuration routines operating with the computer 8. However, unlike the device nodes for the devices 20, such as the network adapter 401, each device node for a network configuration routine contains a single attribute, specifically the identity of the corresponding network configuration routine. This identity information is obtained from the registry 153 by the network driver interface 403, which operates as an enumerator 150 during the enumeration process and is used to populate the device nodes for each network configuration routine. Thus, it will be appreciated that the device nodes associated with network configuration routines include the layer identification codes for the corresponding routines.

Referring now to FIGS. 6 and 15 and to FIG. 18A, which illustrates the tree-like data structure of the hardware tree 152 for the network configuration shown in FIG. 15, the hardware tree 152 contains a set of device nodes, including a device node 500 for the local bus, a device node 501 for the ISA bus, and a device node 502 for the network adapter 401. These device nodes represent certain hardware components of the computer 8. For the network configuration routines of the network adapter 401, the hardware tree 152 includes device nodes representing the protocols 404, redirectors 406, and servers 408 of the network system 400. In particular, for the network architecture of FIG. 15, device nodes 504, 506, and 508 respectively represent the NetBEUI, IP, and IPX protocols. The device nodes 510 and 512 respectively represent a SMB redirector and SMB server, device node 514 represents a SMB redirector and device nodes 516 and 518 respectively represent a NCP redirector and a SMB redirector.

A branch between any pair of the device nodes of the hardware tree 152 indicates that the connected device nodes share a common link. For example, upon entering the hardware tree 152, the device node 501 for the ISA bus can be reached only by first passing through the local bus device node 500 and a branch 520. This defines an interconnection between those system busses 18 (FIG. 1), thereby supplying an indication that the ISA bus is connected to the local bus. Likewise, the network adapter 401 is connected to the ISA bus because a branch 522 extends from the ISA bus device node 501 to the device node 502. In similar fashion, the branches 524, 526, and 528 represent the interface 412 supplying a communications link between the protocols 404 and the network adapter 401. In addition, branches 530, 532, 534, 536, and 538 represent individual interfaces 414 connecting the protocols 404 to their respective redirectors 406 and servers 408.

To emphasize the construction of the hardware tree 152 for a computer having an installed network adapter card, the hardware tree 152 shown in FIG. 18A represents the network configuration in FIG. 15 and does not include device nodes for the remaining system busses 18 and devices 20 of the computing system 8. Nevertheless, it will be understood that the hardware tree 152 for the computing system 8 typically can include device nodes for both hardware and software components.

FIG. 18B illustrates the data structure for a representative device node for a network configuration routine, in this case, the device node 504 for the NetBEUI protocol. Referring to FIGS. 18A and 18B, the device node 504 preferably includes the layer identification code for the NetBEUI protocol. specifically “NetBEUI\0000.” A review of this layer identification code indicates that the NetBEUI protocol is assigned a name “NetBEUI” and is the first identified protocol of its type for the network adapter 401, as evidenced by the instance number “0000.”

FIGS. 19A and 19B are flow chart diagrams that illustrate in detail the preferred steps for a method for configuring the network configuration routines for a network adapter card operating with a computer. This configuration method will be described by applying the steps illustrated in FIGS. 19A and 19B to the network configuration shown in FIG. 15. Although this application serves to illustrate the iterative nature of the configuration process, it will be understood that the present invention is not limited to operation with this specific network configuration and is useful for numerous other network configurations.

Referring now to FIGS. 6, 14, 15, 17, and 19A and 19B, the network software configuration process is initiated at the START step and proceeds to step 550, in which device information is collected from each of the devices 20 on the system busses 18, including the-network adapter 401 on the integrated bus 15. A device node is then created in the hardware tree 152 for each of the detected devices, including the network adapter 401. In turn, based upon the collected device information, resource elements of the resources 14 are allocated in step 552 to each of the detected devices. In step 554, the device drivers 156 are loaded for the detected devices to enable these configured devices to operate with the computer 8.

For the network adapter 401, the selected device driver 156 is one of the network drivers 402 that is compatible with the detected network adapter 401. The network driver is identified by searching the hardware archive 184 of the registry 153 for an entry having the identification code for the particular network adapter 401. For the network adapter 401 shown in FIG. 15 and described in Table 5, the DEC DEPCA card has the identification code “*PNP80E7\0000.” This registry entry identifies the corresponding device driver for the network adapter card, the network driver 402 (“Net\0000”). In turn, the configuration manager 158 calls the network driver interface 403, which operates as a device loader or “DevLoader.” The network driver interface 403 responds by calling a V×Dynaloader (not shown) to load identified network driver 402 into memory 22 (FIG. 1). The loaded network driver 402 subsequently calls the network driver interface 403 to obtain driver configuration parameters. The network driver interface 403 responds to this call by locating the driver configuration parameters in the software archive 182 under the network driver entry (“Net\0000”) for the detected network adapter 401 (Table 12). The network driver 402 calls for each desired configuration parameter by name and, in turn, the network driver interface 403 reads the configuration parameter from the registry entry and returns the values to the network driver 402. To insure that the network driver interface 403 receives all configuration messages on behalf of the loaded network driver 402, the network driver interface 403 registers with the configuration manager 158 by sending a system message “CONFIG Register Driver.”

Proceeding now to step 555, one of the interfaces 412 or 414 of the network system 400 is selected. For this initial pass, the interface 412 associated with the network adapter 401 is selected and responds to the loading and configuration of the network driver 402 that supports this device. For the DEC DEPCA card of FIG. 15, the interface identification code is identical to the identification code for this device, specifically “*PNP80E7\0000.”

In step 556, the layers for the selected interface are identified by using the corresponding interface identification code as a key to search the hardware archive 184 of the registry 153 for an associated first entry 432. This search is supported by the network driver interface 403, which operates as an enumerator in response to a call from the configuration manager 158 to enumerate the “virtual devices” or layers connected to a particuler “virtual bus” or interface. For this initial pass through the steps of the configuration process, the network driver interface 403 is instructed to enumerate the layers on the interface of the network adapter 401. i.e. the interface 412. The network driver interface 403 uses the interface identification code for the network adapter 401 (*PNP80E7\0000) as a key to locate the registry entry for the network adapter card (Table 5).

In step 558, the layers associated with the particular interface are identified by examining one or more layer identification codes stored within the first entry. Specifically, the registry entry for the network adapter 401 contains a Bindings subkey, which includes one or more layer identification codes that identify the protocols 404 which are bound to the network adapter card. For the network architecture in FIG. 15, the layer identification codes include NETBEUI\0000, MSTCP\0000, and NWLINK\0000. which respectively designate the NetBEUI, IP, and IPX protocols.

In step 560, device nodes for the identified layers on the selected interface are created within the hardware tree 152. For this example, the network driver interface 403 calls the configuration manager 158 to create in the hardware tree 152 a device node for each of the protocols 404 listed by the Binding subkey of the first entry 432. The configuration manager 158 subsequently calls the device loader to load the driver for each of the protocols identified by the newly created device nodes. The network driver interface 403 preferably operates as the device loader for the protocols 404 of the network system 400. The drivers for the identified layers are loaded in a sequential manner by the device loader. Accordingly, in step 561, a layer is selected to initiate the loading operation for its corresponding driver. For the purposes of this illustration, the NetBEUI protocol is selected.

In step 562, the device loader searches the registry 153 to locate a second entry 434 Containing information for the selected layer. This search is conducted by using a key to screen the registry entries, specifically the layer identification code for the layer selected in step 561. Thus, one of the layer identification codes supplied by the first entry 432 for the network adapter 401 is used to locate the second entry 434 associated with the identified layer. For the selected NetBEUI protocol, the layer identification code is “NETBEUI\0000” (Tables 5 and 6).

The second entry also includes a driver identification code that identifies the driver for the selected layer. Accordingly, in step 564, the driver for the selected layer is identified by reading the driver identification code in this registry entry. For the NetBEUI protocol, the second entry 434 includes a Driver data field which identifies its driver by the driver identification code “NetTrans\0000” (Table 6).

In step 566, the registry 153 is searched for a third entry 436 by using a key based upon the driver identification code supplied by the associated second entry 434. This third entry 436 is preferably located within the software archive 182 of the registry 153, which generally contains registry entries directed to device drivers 156 (including network drivers 402) and drivers for network configuration routines. The driver identification code of the second entry 434 operates as a pointer to the corresponding third entry 436, which can include one or more data fields that define the configuration parameters for the identified driver. For the third entry 436 identified by the key “NetTrans\0000,” no configuration parameters are listed because the driver for the NetBEUI protocol does not require these parameters (Table 13).

In step 568, the driver identified in this third entry 436 is loaded within the memory 22 (FIG. 1). In particular, this “NetTrans\0000” driver for the NetBEUI protocol is loaded by a V×Dynaloader (not shown), which is called by the network driver interface 403. At this time, the network driver interface 403 also registers with the configuration manager 158 as the driver for the selected layer, in this case, the NetBEUI protocol. This allows the network driver interface 403, which operates as the enumerator for the network configuration routines, to receive all configuration messages destined for the NetBEUI protocol.

In step 570, the configuration parameters stored in the third entry 436, if any, are supplied to the loaded driver for the selected protocol 404, thereby completing the driver loading operation for a selected layer. For the example of a protocol layer, if configuration parameters are listed within the third entry 436, the network driver interface 403 instructs the protocol 404 to bind to the network adapter 401. The protocol 404 then issues a request for the network driver interface 403 to access the third entry 436 to obtain configuration parameters for the driver of the protocol 404. Specifically, the protocol 404 asks for each desired configuration tarameter by name, one at a time, and, in turn, the network driver interface 403 locates the configuration parameters in the third entry 436 and returns the values to the driver.

In step 572, an inquiry is conducted to determine whether a driver has been loaded and configured for each of the remaining identified layers of the selected interface. If the response is negative, then the “NO” branch is followed to step 561 to continue the driver loading operations. For this example, both the IP and IPX protocols identified in step 558 require appropriate drivers. By completing in sequential fashion the loop formed by the steps 561-572, the drivers for these remaining protocols are loaded and configured in a manner similar to the NetBEUI protocol.

If the response to the query in step 572 is positive, then the “YES” branch is followed to step 574. In step 574, an inquiry is conducted to determine whether layers are associated with other interfaces of the network system 400. If the answer is positive, the “YES” branch is followed to step 555. In contrast, the “NO” branch is followed to the END step if the response in step 574 is negative.

For the network configuration shown in FIG. 15, it will be appreciated that the remaining layers connected to the NetBEUI, IP, and IPX protocols via the interfaces 414 also require configuration. Accordingly, the loop formed by the steps 555-574 is followed until all remaining network configuration routines, including the assigned redirectors 406 and servers 408, are configured. The configuration process for these layers is similar to the above-described process for the protocols 404, with the exception that the first entry 432 is now identified by the interface identification code for the selected protocol. The protocols 404 operate as both “virtual devices” and “virtual busses” because the protocols 404 can be “connected” to the network adapter 401 and, in turn, redirectors 406 and servers 408 can be “connected” to one or more of the protocols 404. Thus, for an interface 414 selected in step 555, such as the interface between the NetBEUI protocol and the SMB redirector and SMB server, the interface identification code is identical to the layer identification code for the NetBEUI protocol, namely “NetBEUI\0000” (Table 6)

In response to loading each of the protocols 404 on the interface 412, the network driver interface 403 registers with the configuration manager 158 as the enumerator for each of the interfaces associated with those routines, namely, the interfaces 414. Thus, the configuration manager 158 calls the network driver interface 403 to operate as an enumerator and to identify the layers associated with each of these remaining interfaces. In step 556, for a selected interface 414, namely the NetBEUI protocol, the network driver interface 403 searches the registry 153 to determine the layers associated with this selected interface. Specifically, the network device 403, operating as an enumerator, uses the interface identification code for the NetBEUI protocol as a key to locate the appropriate first entry 432 in the registry 153.

In step 558, the network driver interface 403 identifies the layers for the selected interface 414 by reviewing each layer identification code contained in the first entry 432. The Bindings subkey within this registry entry contains one or more layer identification codes that uniquely identify the remaining network configuration routines for this interface. For the NetBEUI protocol, the Bindings subkey includes the interface identification codes “VREDIR\0000” and “VSER VER\0000,” which respecivelv identify the SMB redirector and the SMB server (Table 6).

In step 560, device nodes are created in the hardware tree 152 for each layer associated with the selected interface 414. Specifically, for each identified layer associated with the selected interface 414, the network driver interface 403 calls the configuration manager 158 to create a device node in the hardware tree 152. For the interface 414 associated with the NetBEUI protocol, device nodes for the SMB redirector and the SMB server are added for the hardware tree. As shown in FIG. 17A, these device nodes are connected to the device node for the NetBEUI protocol and are identified by their respective layer identification codes. In turn, the network driver interface 403 calls the configuration manager 158 and registers as the device loader for the layers identified by the new device nodes.

To initiate the sequential loading of drivers for the layers associated with the selected interface 414, one of these layers is selected in step 561. For this example, the SMB redirector associated with the NetBEUI protocol is selected to illustrate this loading operation.

In step 562, the layer identification code associated with one of the identified layers is used as a key to search the hardware archive 184 of the registry 153 for a second entry 434. For the SMB redirector, the layer identification code “VREDIR\0000” is used as a key to locate the appropriate second entry 434 (Table 9). This search is conducted by the V×Dynaloader (not shown) in response to a command from the network driver interface 403, which is operating as a device loader.

In step 564, the driver for the selected layer is identified by locating the driver identification code in the second entry 434. For the SMB redirector, the driver is identified within the “Driver” data field by the driver identification code “NetClient\0000” (Table 9).

In step 566, the driver identification code is used as a key to search the software archive 182 of the registry 153 for a third entry 436 for the selected layer. For the example of the SMB redirector, the third entry 436 identified by the driver identification code “NetClient\0000” is located in the registry 153 (Table 16). The identified driver is loaded within the system memory 22 bl the V×Dynaloader in step 566.

In step 570, the configuration parameters for the driver of the selected layer are supplied to this driver. Because both the redirectors 406 and the servers 408 operate as device drivers, these network configuration routines search the third entry 436 in the registry 153 to read their configuration parameters. Thus, for the example of the SMB redirector, this network configuration routine accesses the third entry 436 identified by the driver identification code “NetClient\0000” to read its configuration parameters in sequential fashion (Table 16).

Upon loading the driver for the SMB redirector, this layer registers with the configuration manager 158. The redirectors 406 and the servers 408 of the network system 400 register with the configuration manager 158 as a device driver, thereby allowing these network configuration routines to receive all configuration messages for these layers. In contrast, for each of the protocols 404. the network driver interface 403 registers with the configuration manager 158.

Upon completing the loading operation for the driver for the selected layer. an inquiry is conducted in step 572 to determine whether a driver has been loaded and configured for each of the remaining identified layers of the selected interface 414. If the response is negative, the “NO” branch followed to the step 562 to continue the loading of these remaining identified layers. However, if the response is positive, the “YES” branch is followed from step 572 to step 574. In step 574, an inquiry is completed to determine whether there are additional interfaces within the network system 400. If so, the “YES” branch is followed to the step 556 to continue the process. In contrast, if the response is negative, the “NO” branch is followed to the END step.

For the network configuration shown in FIG. 15, the process continues for the SMB server associated with the NetBEUI protocol and for the remaining redirectors and/or servers for the remaining protocols, specifically the IP and the IPX protocols.

Although the preferred steps of the network configuration method have been described with respect to a specific network system 400, i.e., the network configuration of FIG. 15, it will be understood that the invention is equally applicable to other network configurations and is not limited to this representative configuration. Furthermore, this network configuration system can support the automated configuration of more than one network adapter card installed within a computer. Accordingly, those skilled in the arc will recognize that the principles of the present invention can be extended to other network architectures and are not limited to the software layers or interfaces of the OSI model described herein. In particular, the inventors believe that the present invention is extendible to present and future network architectures and network adapter-type devices.

Although the preferred environment for the present invention is a personal computer, it will be appreciated that the invention is also applicable to other types of data processing systems having resources that support the processing operations of the data processing system. Indeed, those skilled in the art will recognize that the principles of the present invention can be extended to other computer architectures and operating systems and are not limited to standard computer architectures or the preferred operating system described herein. Specifically, the inventors envision that the present invention is extendible to present and future bus architectures, device types, and network configuration routines.

In view of the foregoing, it will be understood that the present invention provides a system for automatically configuring devices for operation with a computer. For devices that are capable of identifying themselves and declaring their services and resource requirements, the configuration system supports installation and configuration of such devices without user intervention. Devices of the computer are configured by identifying the devices, determining the resource usage of those devices, detecting and resolving potential conflicting uses of the resources, and allocating the resources for use by the devices.

Device information is collected from the presently installed devices and stored within computer memory. This device information identifies the installed devices and supplies the resource requirements for those devices. Furthermore, the computer memory can maintain the assigned resource elements for the identified devices of the computer. Accordingly, the present invention supplies a database containing the device identities, resource requirements, and assigned resource elements for each of the devices installed within the computer.

It will be appreciated that this database can be accessed by the user to support a review of the present device configuration for the user's computer. Likewise, this device information can be remotely accessed if the computer is connected to a computer network or to a modem. Thus, the present invention also supports configuration management for a family of computers by enabling a central party to access and review the device configuration information for each of the computers within that family.

For configuration of network adapter devices, the present invention further includes (1) the identification of “virtual devices” or layers connected to “virtual busses” or interfaces, and (2) the loading of the identified virtual devices for each of the virtual busses. In response to loading the driver for the network adapter device, each of the virtual devices configured for connection to the network adapter is enumerated and, in turn, drivers for these virtual devices are loaded. This process continues for each virtual device until no new virtual busses are identified.

To identify virtual devices “logically” connected to a particular virtual bus, a database of the computer is searched to locate a first entry having an interface identification code that is associated with the particular virtual bus. This first entry can also include one or more layer identification codes that uniquely define the identity of the virtual devices for this virtual bus.

To load an identified virtual device, a second entry having the layer identification code for this virtual device is located within the computer database. The second entry also can include a driver identification code that uniquely defines a driver for this virtual device. A third entry within the database is then located by using the driver identification code as a key to search the database. The third entry can contain configuration parameters for the driver of the identified virtual device. In response to this driver-related information, the driver for the identified virtual device is loaded within system memory of the computer. The configuration parameters, if any, are supplied to the driver to complete this loading operation. This process is repeated until all virtual devices associated with the virtual busses are loaded and configured.

While there has been shown and described the preferred embodiment of the invention, it will be evident to those skilled in the art that various modifications and changes may be made thereto without departing from the spirit and the scope of the invention as set forth in the appended claims and equivalents thereof. 

We claim:
 1. For a system for configuring a computer, said computer characterized by at least one system bus, a plurality of resources comprising memory addresses, direct memory access channels, interrupts, and input/output ports, and devices connected to each system bus, each device associated with device information that uniquely identifies said corresponding device and defines usage requirements of said resources for said corresponding device, said configuring system, responsive to certain events causing an asynchronous change in the operating state of said computer, for configuring each device by collecting said device information from each memory storage device, for determining at least one possible logical device configuration based upon the collected device information, allocating said resources for each device in response to said device information, and loading a device driver for each device, wherein at least one of said devices is a network adapter including a plurality of layers associated with interfaces, said layers comprising at least one of protocols, redirectors, and servers, a method for automatically configuring said layers of each network adapter without manual intervention and without prior configuration information, in response to loading said device driver corresponding to said network adapter, comprising the steps, (a) identifying each layer associated with a particular one of said interfaces for said corresponding network adapter; (b) loading each identified layer; and (c) repeating steps (a)-(b) for each of the remaining ones of said interfaces.
 2. The method of claim 1, Herein said identifying step comprises searching a database of said computer and locating a first entry having an interface identification code that identifies said particular interface, said first entry further having a layer identification code for each layer associated with said particular interface, each layer identification code uniquely defining the identity of a corresponding layer.
 3. The method of claim 2, wherein said identifying step further comprises storing each layer identification code within one of a plurality of hierarchically-arranged device nodes within system memory of said computer, said device nodes defining the present configuration of said network adapter.
 4. The method of claim 2, wherein said step of loading each identified layer comprises: (a) locating within said database a second entry having one of said layer identification code for a selected layer, said second entry further having a driver identification code that uniquely defines a driver for said selected layer; (b) locating within said database a third entry having said driver identification code, said third entry containing configuration parameters for said driver for said selected layer; (c) loading said driver for said selected layer within system memory of said computer; (d) supplying said configuration parameters to said driver for said selected layer; and (e) repeating steps (a)-(d) for each of said remaining layers associated with said particular interface.
 5. A system for automatically configuring a computer without manual intervention and without prior configuration information, said computer characterized by a system bus and a plurality of computer resources comprising memory addresses, direct memory access channels, and input/output ports, said system comprising: a plurality of devices connected to said system bus, at least one of said devices being a network adapter, each device connected to a memory storage unit that stores device information for a corresponding one of said devices, said device information uniquely identifying said corresponding device and defining usage requirements of said computer resources for said corresponding device; configuring means for configuring each device in response to certain events causing an asynchronous change in the operating state of said computer, said configuring means operative to collect said device information from each memory storage unit, to determine at least one possible logical device configuration based upon the collected device information, and to allocate said computer resources for each device in response to said device information to prevent a conflicting use of said computer resources by each device; and network configuring means for configuring each of a plurality of layers associated with said network adapter, said layers comprising at least one of protocols, redirectors, and servers, each of said layers associated with one of a plurality of interfaces.
 6. The system of claim 5, wherein said network configuring means comprises: identifying means for identifying a selected layer associated with a particular interface by searching a database of said computer and locating a first entry having an identification code that identifies said particular interface, said first entry further having a layer identification code that uniquely defines the identity of said selected layer; said identifying means further operative to locate within said database a second entry having said layer identification code, said second entry further having a driver identification code that uniquely defines a driver for said layer selected, and to locate within said database a third entry having said driver identification code, said third entry containing configuration parameters for said driver; and a device loader for loading said driver for said selected layer within system memory of said computer.
 7. The system of claim 5, wherein said events include at least one of powering said computer, connecting another one of devices to said selected system bus, and removing one of said devices from said selected system bus.
 8. A computer system characterized by resources and devices connected to at least one of a plurality of system buses, said resources comprising at least one of memory addresses, direct memory access channels, interrupts, and input/output ports, said devices including at least one network adapter, each network adapter comprising a plurality of layers associated with interfaces, said layers comprising at least one of protocols, redirectors, and servers, and a program module for automatically configuring the devices of the computer system without manual intervention and without prior configuration information, the computer system comprising: a processing unit; and a memory, coupled to the processing unit, for storing the program module; the processing unit, responsive to instructions of the program module, operative to (a) collect device information for each of said devices connected to a selected one of said system busses, said device information uniquely identifying a corresponding one of said devices, said device information further describing characteristics of said corresponding device, wherein the device information is utilized to determine at least one possible logical device configuration; (b) allocate said resources for each of said devices in response to said device information to prevent a conflicting use of said resources by said devices; (c) load a device driver for each of said devices in response to said allocation of said resources, each device driver operative to enable said devices to communicate with said computer; (d) repeat tasks (a)-(c) for each remaining one of said system busses; and in response to loading said device driver for each network adapter, the processing unit is operative to (e) identify each layer associated with a particular one of said interfaces for a corresponding network adapter; (f) load each identified layer; and (g) repeat tasks (e)-(f) for each remaining one of said interfaces for said corresponding network adapter.
 9. The computer system of claim 8, wherein said processing unit identifies each layer by searching a database of said computer and locating a first entry having an interface identification code that identifies said particular interface, said first entry further having a layer identification code for each layer associated with said particular interface, each layer identification code uniquely defining the identity of a corresponding layer.
 10. The computer system of claim 9, wherein said processing unit loads each identified layer by: (a) locating within said database a second entry having one of said layer identification code for a selected layer, said second entry further having a driver identification code that uniquely defines a driver for said selected layer; (b) locating within said database a third entry having said driver identification code, said third entry containing configuration parameters for said driver for said selected layer; (c) loading said driver for said selected layer within system memory of said computer; (d) supplying said configuration parameters to said driver for said selected layer; and (e) repeating tasks (a)-(d) for each of said remaining layers associated with said particular interface.
 11. In a computer system characterized by resources and devices connected to at least one of a plurality of system busses, said resources comprising at least one of memory addresses, direct memory access channels, interrupts, and input/output ports, said devices including at least one network adapter, each network adapter comprising a plurality of layers associated with interfaces, said layers comprising at least one of protocols, redirectors, and servers, a computer-readable medium on which is stored a program module for automatically configuring the devices of the computer system without manual intervention and without prior configuration information, the program module comprising instructions which, when executed by the computer, performs the steps of: (a) collecting device information for each of said devices connected to a selected one of said system busses, said device information uniquely identifying a corresponding one of said devices, said device information further describing characteristics of said corresponding device, wherein the device information is utilized to determine at least one possible logical device configuration; (b) allocating said resources for each of said devices in response to said device information to prevent a conflicting use of said resources by said devices; (c) loading a device driver for each of said devices in response to said allocation of said resources, each device driver operative to enable said devices to communicate with said computer; (d) repeating steps (a)-(c) for each remaining one of said system busses; and in response to loading said device driver for each network adapter, (e) identifying each layer associated with a particular one of said interfaces for a corresponding network adapter; (f) loading each identified layer; and (g) repeating steps (e)-(f) for each remaining one of said interfaces for said corresponding network adapter.
 12. The program module of claim 11, wherein said instructions for identifying each layer, when executed by the computer, performs the steps of searching a database of said computer and locating a first entry having an interface identification code that identifies said particular interface, said first entry further having a layer identification code for each layer associated with said particular interface, each layer identification code uniquely defining the identity of a corresponding layer.
 13. The program module of claim 12, wherein said instructions for loading each identified each layer, when executed by the computer, performs the steps of: (a) locating within said database a second entry having one of said layer identification code for a selected layer, said second entry further having a driver identification code that uniquely defines a driver for said selected layer; (b) locating within said database a third entry having said driver identification code, said third entry containing configuration parameters for said driver for said selected layer; (c) loading said driver for said selected layer within system memory of said computer; (d) supplying said configuration parameters to said driver for said selected layer; and (e) repeating tasks (a)-(d) for each of said remaining layers associated with said particular interface. 